Radar apparatus

ABSTRACT

A transmitting array antenna includes a second antenna group placed in a position inside a first antenna group in a first direction and a position different from the first antenna group in a second direction. A receiving array antenna includes a fourth antenna placed in a position outside a third antenna group arranged in the first direction and a position different from the third antenna group in the second direction. An interelement spacing between a receiving antenna of the third antenna group located at an end on a second side is identical to an interelement spacing in the first direction between a transmitting antenna of the first antenna group on the first side and each of the second antenna group. In a case where the first antenna group and the third antenna group are identical in position in the second direction, positions of antennas are different.

BACKGROUND 1. Technical Field

The present disclosure relates to a radar apparatus.

2. Description of the Related Art

In recent years, a radar apparatus has been under consideration whichuses short-wavelength radar transmission signals including microwaves ormillimeter waves that yield high resolution. Further, for improvement inoutdoor safety, there has been a demand for the development of a radarapparatus (wide-angle radar apparatus) that detects objects (targets)including pedestrians, as well as vehicles, in a wide angular range.

For example, as a radar apparatus, a pulse radar apparatus has beenknown which repeatedly emits pulse waves. A signal that is received by awide-angle pulse radar that detects a vehicle or a pedestrian in a wideangular range is one obtained by mixing a plurality of reflected wavesfrom a target (e.g. a vehicle) that is present at a short distance andfrom a target (e.g. a pedestrian) that is present at a long distance.This requires (1) a radar transmitter to be configured to transmit apulse wave or a pulse-modulated wave having an autocorrelationcharacteristic that forms a low-range side lobe (such a characteristicbeing hereinafter referred to as “low-range side lobe characteristic”)and requires (2) a radar receiver to be configured to have a widereception dynamic range.

Examples of how a wide-angle radar apparatus is configured include thefollowing two configurations.

In the first configuration, radar waves are transmitted by mechanicallyor electronically scanning pulse waves or modulated waves withnarrow-angle directional beams (with beams width of approximatelyseveral degrees), and reflected waves are received with narrow-angledirectional beams. The first configuration requires much scanning forhigh resolution and, as such, is less capable of tracking a fast-movingtarget.

The second configuration employs a technique (direction-of-arrival (DOA)estimation) in which reflected waves are received by an array antennaconstituted by a plurality of antennas (antenna elements) and the anglesof arrival of the reflected waves are estimated by a signal-processingalgorithm based on a phase difference in reception due to interelementspacings (inter-antenna spacings). The second configuration, whichallows the angles of arrival to be estimated at a receiving branch evenif scan intervals between transmission beams at a transmitting branchare skipped, achieves a reduction in scanning time and, as such, ishigher in tracking capability than the first configuration. Examples ofdirection-of-arrival estimation methods include a Fourier transformbased on a matrix operation, a Capon method based on an inverse matrixoperation, an LP (linear prediction) method based on an inverse matrixoperation, MUSIC (Multiple Signal Classification) based on an eigenvalueoperation, and ESPRIT (estimation of signal parameters via rotationalinvariance techniques) based on an eigenvalue operation.

Further, as a radar apparatus, a configuration (sometimes referred to as“MIMO radar”) has been proposed which includes a plurality of antennas(array antenna) at a transmitting branch as well as at a receivingbranch and performs beam scanning by signal processing with thetransmitting and receiving array antennas (see, for example, J. Li, P.Stoica, “MIMO Radar with Colocated Antennas,” Signal ProcessingMagazine, IEEE Vol. 24, Issue: 5, pp. 106-114, 2007).

Further, in the MIMO radar, at most as many virtual receiving arrayantennas (hereinafter referred to as “virtual receiving array”) as theproduct of the number of transmitting antenna elements and the number ofreceiving antenna elements are configured by devising an arrangement ofantenna elements in the transmitting and receiving array antennas. Thismakes it possible, with a small number of elements, to bring about aneffect of increasing an effective aperture length of the array antennaand improve angular resolution.

Further, a MIMO radar is also applicable in a case where two-dimensionalvertical and horizontal beam scanning is performed as well as a casewhere one-dimensional vertical or horizontal scanning (angle measuring)is performed (see, for example, P. P. Vaidyanathan, P. Pal, Chun-YangChen, “MIMO radar with broadband waveforms: Smearing filter banks and 2Dvirtual arrays,” IEEE Asilomar Conference on Signals, Systems andComputers, pp. 188-192, 2008).

However, depending on the antenna arrangement of transmitting andreceiving branches in the MIMO radar, there may occur deterioration indetection performance of the radar.

SUMMARY

One non-limiting and exemplary embodiment provides a radar apparatusthat makes it possible to maximally enlarge an aperture length of avirtual receiving array without deterioration in detection performanceof a radar.

In one general aspect, the techniques disclosed here feature a radarapparatus including: a radar transmitter that transmits a radar signalthrough a transmitting array antenna; and a radar receiver thatreceives, through a receiving array antenna, a reflected-wave signalproduced by the radar signal being reflected by a target, wherein thetransmitting array antenna is composed of a first antenna groupincluding a plurality of transmitting antennas arranged in a firstdirection and a second antenna group including at least one transmittingantenna placed in a position inside at least one pair of adjacenttransmitting antennas of the first antenna group in the first directionand a position different from the first antenna group in a seconddirection orthogonal to the first direction, the receiving array antennais composed of a third antenna group including a plurality of receivingantennas arranged in the first direction and a fourth antenna that isone receiving antenna placed in a position outside an end of the thirdantenna group in the first direction and a position different from thethird antenna group in the second direction, an interelement spacingbetween the adjacent transmitting antennas in the first direction is asum of an aperture length of the third antenna group and a spacingbetween the third antenna group and the fourth antenna in the firstdirection, an interelement spacing in the first direction between areceiving antenna of the third antenna group located at an end on asecond side opposite to a first side close to the position in which thefourth antenna is placed and each of the other antennas of the thirdantenna group is identical to an interelement spacing in the firstdirection between a transmitting antenna of the adjacent transmittingantennas located on the same side as the first side and each of thetransmitting antennas of the second antenna group, and in a case wherethe first antenna group and the third antenna group are identical inposition in the second direction, a position of each of the transmittingantennas of the second antenna group in the second direction and aposition of the fourth antenna in the second direction are different.

An aspect of the present disclosure makes it possible to maximallyenlarge an aperture length of a virtual receiving array withoutdeterioration in detection performance of a radar.

It should be noted that general or specific embodiments may beimplemented as a system, a method, an integrated circuit, a computerprogram, a storage medium, or any selective combination thereof.

Additional benefits and advantages of the disclosed embodiments willbecome apparent from the specification and drawings. The benefits and/oradvantages may be individually obtained by the various embodiments andfeatures of the specification and drawings, which need not all beprovided in order to obtain one or more of such benefits and/oradvantages.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a diagram showing an example arrangement of transmitting andreceiving antennas;

FIG. 1B is a diagram showing an example arrangement of a virtualreceiving array;

FIG. 2A is a diagram showing a directivity pattern based on a virtualreceiving array (d_(V)=0.5λ);

FIG. 2B is a diagram showing a directivity pattern based on a virtualreceiving array (d_(V)=0.5λ) FIG. 3A is a diagram showing a directivitypattern based on a virtual receiving array (d_(V)=λ);

FIG. 3B is a diagram showing a directivity pattern based on a virtualreceiving array (d_(V)=2λ);

FIG. 4 is a block diagram showing a configuration of a radar apparatusaccording to Embodiment 1;

FIG. 5 is a diagram showing examples of radar transmission signalsaccording to Embodiment 1;

FIG. 6 is a block diagram showing another configuration of a radartransmission signal generator according to Embodiment 1;

FIG. 7 is a diagram showing examples of timings of transmission of radartransmission signals and examples of measuring ranges according toEmbodiment 1;

FIG. 8A is a diagram showing an example arrangement of transmitting andreceiving antennas according to Embodiment 1;

FIG. 8B is a diagram showing an example arrangement of a virtualreceiving array according to Embodiment 1;

FIG. 9A is a diagram showing another example arrangement of transmittingand receiving antennas according to Embodiment 1;

FIG. 9B is a diagram showing another example arrangement of a virtualreceiving array according to Embodiment 1;

FIG. 10A is a diagram showing an example arrangement of transmitting andreceiving antennas according to Variation 1 of Embodiment 1;

FIG. 10B is a diagram showing another example arrangement of a virtualreceiving array according to Variation 1 of Embodiment 1;

FIG. 11A is a diagram showing an example arrangement of transmitting andreceiving antennas according to Variation 2 of Embodiment 1;

FIG. 11B is a diagram showing another example arrangement of a virtualreceiving array according to Variation 2 of Embodiment 1;

FIG. 12A is a diagram showing an example arrangement of transmitting andreceiving antennas according to Variation 3 of Embodiment 1;

FIG. 12B is a diagram showing another example arrangement of a virtualreceiving array according to Variation 3 of Embodiment 1;

FIG. 13A is a diagram showing an example arrangement of transmitting andreceiving antennas according to Embodiment 2;

FIG. 13B is a diagram showing an example arrangement of a virtualreceiving array according to Embodiment 2;

FIG. 14A is a diagram showing an example arrangement of transmitting andreceiving antennas according to Variation 1 of Embodiment 2;

FIG. 14B is a diagram showing another example arrangement of a virtualreceiving array according to Variation 1 of Embodiment 2;

FIG. 15 is a diagram showing an example arrangement of transmitting andreceiving antennas according to Variation 1 of Embodiment 2;

FIG. 16 is a diagram showing an example arrangement of transmitting andreceiving antennas according to Variation 1 of Embodiment 2;

FIG. 17A is a diagram showing an example arrangement of transmitting andreceiving antennas according to Variation 2 of Embodiment 2;

FIG. 17B is a diagram showing another example arrangement of a virtualreceiving array according to Variation 2 of Embodiment 2;

FIG. 18A is a diagram showing an example arrangement of transmitting andreceiving antennas according to Variation 3 of Embodiment 2;

FIG. 18B is a diagram showing another example arrangement of a virtualreceiving array according to Variation 3 of Embodiment 2;

FIG. 19A is a diagram showing an example arrangement of transmitting andreceiving antennas according to another embodiment;

FIG. 19B is a diagram showing another example arrangement of a virtualreceiving array according to another embodiment;

FIG. 20A is a diagram showing an example arrangement of transmitting andreceiving antennas according to another embodiment; and

FIG. 20B is a diagram showing another example arrangement of a virtualreceiving array according to another embodiment.

DETAILED DESCRIPTION

As mentioned above, a MIMO radar constituting a virtual receiving arrayis also applicable in a case where two-dimensional vertical andhorizontal beam scanning is performed as well as a case whereone-dimensional vertical or horizontal scanning (angle measuring) isperformed.

As an example, FIG. 1A shows a transmitting array antenna including fourtransmitting antennas (Tx #1 to Tx #4) arranged in a vertical directionand a receiving array antenna including four receiving antennas (Rx #1to Rx #4) arranged in a horizontal direction. In FIG. 1A, thetransmitting antennas are placed at regular spacings (d_(V)) in avertical direction and the receiving antennas are placed at regularspacings (d_(H)) in a horizontal direction.

FIG. 1B shows a virtual receiving array including transmitting andreceiving array antennas of an antenna arrangement shown in FIG. 1A. Thevirtual receiving array shown in FIG. 1B is composed of sixteen virtualreceiving antenna elements (VA #1 to VA #16), i.e. a four-by-fourrectangular matrix of antennas arranged in vertical and horizontaldirections. In FIG. 1B, the horizontal and vertical interelementspacings of the virtual receiving array are d_(H) and d_(V),respectively. That is, the horizontal and vertical aperture lengthsD_(H) and D_(V) of the virtual receiving array are 3d_(H) and 3d_(V),respectively.

FIGS. 2A and 2B show a Fourier beam pattern directed in horizontal0-degree and vertical 0-degree directions in a case where the horizontalinterelement spacing is given as d_(H)=0.5λ and the verticalinterelement spacing is given as d_(V)=0.5λ in an antenna arrangement ofa MIMO radar shown in FIGS. 1A and 1B. It should be noted that λ denotesthe wavelength of a radar carrier wave.

As shown in FIGS. 2A and 2B, a main beam (main lobe) is formed in thehorizontal 0-degree and vertical 0-degree directions. Note here that anarrower beam width of the main beam means higher angular separationperformance with respect to a plurality of targets. For example, inFIGS. 2A and 2B, the 3 dB beam width is approximately 26 degrees.Further, as shown in FIGS. 2A and 2B, there are side lobes generatedaround the main beam. In a radar apparatus, a side lobe causes falsedetection as a virtual image. For this reason, a lower peak level of aside lobe means a lower probability of false detection of the side lobeas a virtual image in the radar apparatus. In FIGS. 2A and 2B, the powerratio (peak side lobe ratio) to the peak level of a side lobe normalizedby the peak level of the main beam is approximately −13 dB.

For the radar apparatus to have a wider range of detection, it iseffective to use a high-gain antenna. For example, antenna gain can beimproved by narrowing the directivity (beam width) of an antenna.Further, for an antenna to have narrower directivity, it is necessary towiden the aperture plane of the antenna. This makes the antenna largerin size.

Further, for an antenna to have narrower directivity, a sub-arrayantenna (sub-arrayed antenna elements) of a configuration in which aplurality of antenna elements are serially fed is sometimes used as anantenna configuration. For example, in a radar apparatus (on-boardradar) that is situated on board a vehicle or the like, a sub-arrayantenna configured by lining up a plurality of antenna elements in avertical direction is used for narrow vertical directivity (see, forexample, J. Wenger, “Automotive mm-wave radar: status and trends insystem design and technology,” IEE Colloquium on Automotive Radar andNavigation Techniques (Ref. No. 1998/230), 1998). This makes it possibleto improve vertical antenna gain, bringing about an effect of reducingwaves that are reflected on a road surface or the like in directions inwhich they do not need to be reflected.

However, in a case where such a sub-array antenna is used as an antennaelement that constitutes a transmitting array antenna or a receivingarray antenna, the interelement spacing of the array antenna is hardlymade narrower than the size of the sub-array antenna. For example, asub-array antenna constituted by antenna elements arranged in a verticaldirection has a size of one wavelength or longer. For example, in a caseof using a sub-array antenna in a vertical direction in the MIMO radarshown in FIG. 1A, it is necessary to widen the vertical interelementspacing d_(V) to one wavelength or longer.

FIGS. 3A and 3B show an example of a Fourier beam pattern directed inhorizontal 0-degree and vertical 0-degree directions in a case where thevertical interelement spacing d_(V) is one wavelength (λ) or longer in atransmitting and receiving antenna arrangement of the MIMO radar shownin FIG. 1A. It should be noted that FIGS. 3A and 3B do not take intoaccount the directivity of single antenna elements sub-arrayed in avertical direction.

Further, in FIG. 3A, the vertical interelement spacing is given asd_(V)=λ and the horizontal interelement spacing is given as d_(H)=0.5λ,and in FIG. 3B, the vertical interelement spacing is given as d_(V)=2λand the horizontal interelement spacing is given as d_(H)=0.5λ.

As shown in FIGS. 3A and 3B, a main beam (main lobe) is directed in thehorizontal 0-degree and vertical 0-degree directions, and there arevertically high-level side lobes (grating lobes) generated around themain beam. In FIGS. 3A and 3B, the peak side lobe ratio is 0 dB.Further, in FIG. 3B (d_(V)=2λ), the vertically high-level side lobes(grating lobes) are generated at narrower angular intervals than in FIG.3A (d_(V)=λ). That is, such a propensity is shown that the wider thevertical interelement spacing d_(V) becomes, the narrower angularintervals the side lobes (grating lobes) are generated at.

In this way, the radar apparatus requires a wider vertical interelementspacing with an increase in vertical antenna size, so that it becomeseasy for a grating lobe to be generated at such an angle as to becomparatively close to the main beam. For this reason, in a case wherethe angular range of detection assumed by the radar apparatus is widerthan the angles at which the grating lobes are generated, the radarapparatus has a higher probability of erroneously detecting a false peakattributed to a grating lobe as a target in the angular range ofdetection, so that there arises a problem of deterioration in detectionperformance of the radar apparatus.

An aspect of the present disclosure maximally enlarges the vertical andhorizontal aperture lengths of a virtual receiving array withoutdeterioration in detection performance of a radar apparatus inperforming two-dimensional vertical and horizontal beam scanning withuse of a MIMO radar. Using such a virtual receiving array makes itpossible to improve angular resolution with a small number of antennaelements.

An embodiment of the present disclosure is described in detail belowwith reference to the drawings. It should be noted that, in theembodiment below, the same constituent elements are given the samereference numerals, and duplication of description is omitted.

The following describes, as a radar apparatus, a configuration in whicha transmitting branch sends out different time-division multiplexedtransmission signals through a plurality of transmitting antennas and areceiving branch demultiplexes each of the transmission signals andperforms a receiving process. However, without being limited to thisconfiguration, the radar apparatus may alternatively be configured suchthat the transmitting branch sends out different frequency-divisionmultiplexed transmission signals through the plurality of transmittingantennas and the receiving branch demultiplexes each of the transmissionsignals and performs a receiving process. Similarly, the radar apparatusmay alternatively be configured such that the transmitting branch sendsout time-division multiplexed transmission signals through the pluralityof transmitting antennas and the receiving branch performs a receivingprocess.

Embodiment 1 Configuration of Radar Apparatus

FIG. 4 is a block diagram showing a configuration of a radar apparatus10 according to Embodiment 1.

The radar apparatus 10 includes a radar transmitter (transmittingbranch) 100, a radar receiver (receiving branch) 200, and a referencesignal generator 300.

The radar transmitter 100 generates high-frequency (radio-frequency)radar signals (radar transmission signals) in accordance with referencesignals received from the reference signal generator 300. Then, theradar transmitter 100 transmits the radar transmission signals withpredetermined radar transmission periods through a transmitting arrayantenna including a plurality of transmitting antennas 106-1 to 106-Nt.

The radar receiver 200 receives, through a receiving array antennaincluding a plurality of receiving antennas 202-1 to 202-Na,reflected-wave signals produced by the radar transmission signals beingreflected by a target (not illustrated). The radar receiver 200 performssynchronous processing with the radar transmitter 100 by performing thefollowing processing operation with reference to the reference signalsreceived from the reference signal generator 300. That is, the radarreceiver 200 processes the reflected-wave signals received through eachseparate receiving antenna 202 and at least detects the presence orabsence of a target and estimates the direction of the target. It shouldbe noted that the target is an object to be detected by the radarapparatus 10 and examples of the target include vehicles (includingfour-wheel and two-wheel vehicles) or persons.

The reference signal generator 300 is connected to both the radartransmitter 100 and the radar receiver 200. The reference signalgenerator 300 supplies the reference signals to the radar transmitter100 and the radar receiver 200 to synchronize processes in the radartransmitter 100 and the radar receiver 200.

Configuration of Radar Transmitter 100

The radar transmitter 100 includes radar transmission signal generators101-1 to 101-Nt, radio transmitters 105-1 to 105-Nt, and thetransmitting antennas 106-1 to 106-Nt. That is, the radar transmitter100 has the Nt transmitting antennas 106, each of which is connected toa corresponding one of the radar transmission signal generators 101 anda corresponding one of the radio transmitters 105.

Each of the radar transmission signal generators 101 receives referencesignals from the reference signal generator 300, generates timing clocksby multiplying the reference signals by a predetermined number, andgenerates radar transmission signals in accordance with the timingclocks thus generated. Then, the radar transmission signal generator 101repeatedly outputs the radar transmission signals with predeterminedradar transmission periods (Tr). A radar transmission signal isrepresented by r_(z)(k, M)=I_(z)(k, M)+j Q_(z)(k, M). Note here that zdenotes a number corresponding to each transmitting antenna 106 and z=1,. . . , Nt. Note also that j denotes the imaginary unit, k denotesdiscrete time, and M denotes the ordinal number of a radar transmissionperiod.

Each of the radar transmission signal generators 101 includes a codegenerator 102, a modulator 103, and an LPF (low-pass filter) 104. Thefollowing describes each component of the radar transmission signalgenerator 101-z, which corresponds to the zth (where z=1, . . . , Nt)transmitting antenna 106.

Specifically, for each radar transmission period Tr, the code generator102 generates a code a(z)_(n)(n=1, . . . , L) (pulse code) of a codesequence of a code length L. Used as the codes a(z)_(n)(z=1, . . . , Nt)generated by the respective code generators 102-1 to 102-Nt are codesthat are lowly correlated or uncorrelated with one another. Examples ofthe code sequence include a Walsh-Hadamard code, an M sequence code, anda Gold code.

The modulator 103 performs pulse modulation (amplitude modulation, ASK(amplitude shift keying), pulse shift keying) or phase modulation (phaseshift keying) on the code a(z)_(n) received from the code generator 102and outputs a modulated signal to the LPF 104.

The LPF 104 outputs a signal component of the modulated signal receivedfrom the modulator 103 which is below a predetermined limited bandwidthto the transmission switcher 105 as a baseband radar transmissionsignal.

The zth (where z=1, . . . , Nt) radio transmitter 105 generates a radartransmission signal in a carrier-frequency (radio-frequency: RF) band byperforming a frequency conversion on a baseband radar transmissionsignal outputted from the zth radar transmission signal generator 101,amplifies the radar transmission signal thus generated to apredetermined transmission power P [dB], and outputs the radartransmission signal thus amplified to the zth transmitting antenna 106.

The zth (where z=1, . . . , Nt) transmitting antenna 106 emits, into aspace, the radar transmission signal outputted from the zth radiotransmitter 105.

FIG. 5 shows radar transmission signals that are transmitted from the Nttransmitting antennas 106 of the radar transmitter 100. A codetransmission section Tw includes a pulse code sequence of a code lengthL. A pulse code sequence is transmitted during a code transmissionsection Tw of each radar transmission period Tr, and the remainingsection (Tr−Tw) is a no-signal section. One pulse code (a(z)_(n)) issubjected to pulse modulation with No samples, whereby each codetransmission section Tw includes Nr (=No×L) samples. That is, themodulator 103 has a sampling rate of (No×L)/Tw. Further, the no-signalsection (Tr−Tw) includes Nu samples.

It should be noted that the radar transmitter 100 may include a radartransmission signal generator 101 a, which is shown in FIG. 6, insteadof including the radar transmission signal generator 101. The radartransmission signal generator 101 a includes a code storage 111 and a DAconverter 112 instead of including the code generator 102, the modulator103, or the LPF 104, which are shown in FIG. 4. The code storage 111stores in advance code sequences generated by the code generator 102(FIG. 4) and cyclically and sequentially reads out the code sequencesthus stored. The DA converter 112 converts, into an analog signal, acode sequence (digital signal) outputted from the code storage 111.

Configuration of Radar Receiver 200

As shown in FIG. 4, the radar receiver 200 includes the Na receivingantennas 202, which constitute an array antenna. Further, the radarreceiver 200 includes Na antenna system processors 201-1 to 201-Na and adirection estimator 214.

Each of the receiving antennas 202 receives a reflected-wave signalproduced by a radar transmission signal being reflected by a target(object) and outputs the reflected-wave signal thus received to acorresponding one of the antenna system processors 201 as a receivedsignal.

Each of the antenna system processors 201 includes a radio receiver 203and a signal processor 207.

The radio receiver 203 includes an amplifier 204, a frequency converter205, and a quadrature-phase detector 206. The radio receiver 203receives reference signals from the reference signal generator 300,generates timing clocks by multiplying the reference signals by apredetermined number, and operates in accordance with the timing clocksthus generated. Specifically, the amplifier 204 amplifies a receivedsignal received from the receiving antenna 202 to a predetermined level,the frequency converter 205 converts the frequency of the receivedsignal from a high-frequency band into a baseband, and thequadrature-phase detector 206 converts the baseband received signal intoa baseband received signal including an I signal and a Q signal.

The signal processor 207 includes AD converters 208 and 209 anddemultiplexers 210-1 to 210-Nt.

The AD converter 208 receives the I signal from the quadrature-phasedetector 206, and the AD converter 209 receives the Q signal from thequadrature-phase detector 206. The AD converter 208 takes discrete-timesamples of the baseband signal including the I signal and therebyconverts the I signal into digital data. The AD converter 209 takesdiscrete-time samples of the baseband signal including the Q signal andthereby converts the Q signal into digital data.

Note here that each of the AD converters 208 and 209 takes Ns discretesamples for the duration Tp (=Tw/L) of each subpulse of a radartransmission signal. That is, the oversampling number per subpulse isNs.

In the following description, with use of an I signal Ir(k, M) and a Qsignal Qr(k, M), a baseband received signal that is outputted from theAD converters 208 and 209 at discrete time k in the Mth radartransmission period Tr[M] is expressed as a complex signal x(k, M)=Ir(k,M)+j Qr(k, M). Further, in the following, discrete time k has its basis(k=1) at the timing of the start of a radar transmission period (Tr),and the signal processor 207 periodically operates until a sample pointk=(Nr+Nu)Ns/No preceding the end of the radar transmission period Tr.That is, k=1, . . . , (Nr+Nu)Ns/No. Note here that j is the imaginaryunit.

The signal processor 207 includes the Nt demultiplexers 210. Nt is equalto the number of systems that corresponds to the number of transmittingantennas 106. Each of the demultiplexers 210 includes a correlationcalculator 211, an adder 212, and a Doppler frequency analyzer 213. Thefollowing describes a configuration of the zth (where z=1, . . . , Nt)demultiplexer 210.

For each radar transmission period Tr, the correlation calculator 211performs a correlation calculation between a discrete sample value x(k,M) including the discrete sample values Ir(k, M) and Qr(k, M) receivedfrom the AD converters 208 and 209 and the pulse code a(z)_(n) (wherez=1, . . . , Nt and n=1, . . . , L) transmitted by the radar transmitter100. For example, the correlation calculator 211 performs a slidingcorrelation calculation between the discrete sample value x(k, M) andthe pulse code a(z)_(n). For example, the correlation calculation valueAC_((z))(k, M) of a sliding correlation calculation at discrete time kin the Mth radar transmission period Tr[M] is calculated according tothe following equation:

$\begin{matrix}{{A\; {C_{(z)}\left( {k,M} \right)}} = {\sum\limits_{n = 1}^{L}{{x\left( {{k + {N_{s}\left( {n - 1} \right)}},M} \right)}{a(z)}_{n}^{*}}}} & (1)\end{matrix}$

where the asterisk (*) denotes a complex conjugate operator.

The correlation calculator 211 performs correlation calculationsaccording to Eq. (1), for example, over the duration of k=1, . . . ,(Nr+Nu)Ns/No.

It should be noted that the correlation calculator 211 is not limited tothe case of performing correlation calculations over the duration ofk=1, . . . , (Nr+Nu)Ns/No, but may limit a measuring range (i.e. therange of k) according to the range of presence of a target to bemeasured by the radar apparatus 10. This enables the radar apparatus 10to reduce the amount of arithmetic processing that is performed by thecorrelation calculator 211. For example, the correlation calculator 211may limit the measuring range to k=Ns(L+1), . . . , (Nr+Nu)Ns/No−NsL. Inthis case, as shown in FIG. 7, the radar apparatus 10 does not performmeasurements in time sections corresponding to code transmissionsections Tw.

With this, even in such a case where a radar transmission signal sneaksdirectly to the radar receiver 200, the radar apparatus 10 can performmeasurements to the exclusion of the influence of sneaking, as thecorrelation calculator 211 does not execute processing during a periodin which the radar transmission signal sneaks (i.e. a period of at leastless than τ1). Further, in a case where the measuring range (range of k)is limited, the radar apparatus 10 may apply processing in a similarlylimited measuring range (range of k) to processes in the adder 212, theDoppler frequency analyzer 213, and the direction estimator 214, whichwill be described below. This makes it possible to reduce the amount ofprocessing in each component, allowing the radar receiver 200 to consumeless electricity.

The adder 212 performs addition (coherent integration) of correlationcalculation values AC_((z))(k, M), which are received from thecorrelation calculator 211 for each discrete time k of the Mth radartransmission period Tr, over the duration (Tr×Np) of a predeterminednumber (Np) of radar transmission periods Tr. The addition (coherentintegration) process over the duration (Tr×Np) is expressed by thefollowing equation:

$\begin{matrix}{{{CI}_{(z)}\left( {k,m} \right)} = {\sum\limits_{g = 1}^{N_{p}}{A\; {C_{(z)}\left( {k,{{N_{p}\left( {m - 1} \right)} + g}} \right)}}}} & (2)\end{matrix}$

Note here that CI_((z))(k, m) denotes the value of addition (hereinafterreferred to as “correlation additional value”) of correlationcalculation values, Np is an integer of not less than 1, m is an integerof not less than 1 that indicates the ordinal number of the number ofadditions in a case where the number of additions Np that the adder 212performs is a single unit. Further, z=1, . . . , Nt.

The adder 212 performs Np additions by using, as a single unit, anoutput from the correlation calculator 211 obtained with a radartransmission period Tr as a unit. That is, the adder 212 addscorrelation calculation values AC_((z)) (k, Np(m−1)+1) to AC_((z))(k,Np×m) as a single unit at uniform timings of discrete time k and therebycalculates a correlation additional value CI_((z))(k, m) every discretetime k. As a result, the effect of Np additions of correlationcalculation values allows the adder 212 to improve the SNR ofreflected-wave signals in a range where reflected-wave signals from atarget have high correlation. This allows the radar receiver 200 toimprove measurement performance regarding the estimation of the distanceof arrival of the target.

It should be noted that, in order for an ideal gain of addition to beachieved, it is necessary that the phase components of correlationcalculation values have a certain level of uniformity in as manysections of addition as the number of additions Np of correlationcalculation values. That is, it is preferable that the number ofadditions Np be set according to an assumed maximum moving velocity of atarget to be measured. A reason for this is that an increase in theassumed maximum velocity of the target leads to an increase in amount ofvariation in the Doppler frequencies of reflected waves from the target.For this reason, there is a reduction in duration of time for which thecorrelation is high. Therefore, the number of additions Np takes on asmaller value, with the result that the addition performed by the adders212 brings about a smaller gain improvement effect.

The Doppler frequency analyzer 213 performs coherent integration atuniform timings of discrete time k with CI_((z))(k, Nc(w−1)+1) toCI_((z))(k, Nc×w), which are Nc outputs from the adder 212 obtained foreach discrete time k, as a unit. For example, the Doppler frequencyanalyzer 213 performs coherent integration after correcting a phasevariation Φ(fs)=2πfs(Tr×Np)ΔΦ depending on 2Nf different Dopplerfrequencies fsΔΦ according to the following equation:

$\begin{matrix}{{{FT\_ CI}_{(z)}^{Nant}\left( {k,f_{s},w} \right)} = {{\sum\limits_{q = 0}^{N_{c} - 1}{{{CI}_{(z)}\left( {k,{{N_{c}\left( {w - 1} \right)} + q + 1}} \right)}{\exp \left\lbrack {{- j}\; {\varphi \left( f_{s} \right)}q} \right\rbrack}}} = {\sum\limits_{q = 0}^{N_{c} - 1}{{{CI}_{(z)}\left( {k,{{N_{c}\left( {w - 1} \right)} + q + 1}} \right)}{\exp \left\lbrack {{- j}2\pi \; f_{s}T_{r}N_{p}q\; {\Delta\varphi}} \right\rbrack}}}}} & (3)\end{matrix}$

Note here that FT_CI_((z)) ^(Nant)(k, fs, w) is the wth output from theDoppler frequency analyzer 213 and represents a result of the coherentintegration of Doppler frequencies fsΔΦ at discrete time k in the Nantthantenna system processor 201. Note, however, that Nant=1 to Na,fs=−Nf+1, . . . 0, . . . Nf, k=1, . . . , (Nr+Nu)Ns/No, w is an integerof not less than 1, and AO is the phase rotation unit.

This allows each of the antenna system processors 201 to yieldFT_CI_((z)) ^(Nant)(k, −Nf+1, w), FT_CI_((z)) ^(Nant) (k, Nf−1, w),which are results of coherent integration according to 2Nf Dopplerfrequency components for each discrete time k, for the duration(Tr×Np×Nc) of every Np×Nc radar transmission periods Tr. It should benoted that j is the imaginary unit and z=1, . . . , Nt.

In a case where Δ =1/Nc, the aforementioned process in the Dopplerfrequency analyzer 213 is equivalent to performing a discrete Fouriertransform (DFT) operation on outputs from the adder 212 at a samplingfrequency fm=1/Tm at sampling intervals Tm=(Tr×Np).

Further, setting Nf to a power-of-two number allows the Dopplerfrequency analyzer 213 to apply a fast Fourier transform (FFT) operationand reduce the amount of arithmetic processing. It should be noted thatwhen Nf>Nc, performing zero filling such that CI_((z))(k, Nc(w−1)+q)=0in a region where q>Nc makes it possible to similarly apply an FFToperation and reduce the amount of arithmetic processing.

Alternatively, instead of performing an FFT operation, the Dopplerfrequency analyzer 213 may perform a process of serially performingproduct-sum operations according to Eq. (3) above. That is, in responseto CI_((z))(k, Nc(w−1)+q+1), which are Nc outputs from the adder 212obtained for each discrete time k, the Doppler frequency analyzer 213may generate a coefficient exp[−j2πf_(s)T_(r)N_(p)qΔφ] corresponding tofs=−Nf+1, . . . , 0, . . . , Nf−1 and serially perform product-sumoperations. Note here that q=0 to Nc−1.

It should be noted that, in the following description, the wth outputsFT_CI_((z)) ¹(k, fs, w), FT_CI_((z)) ²(k, fs, w), FT_CI_((z)) ^(Na)(k,fs, w) obtained by performing the same processes in the Na antennasystem processors 201 are denoted as a virtual receiving arraycorrelation vector h(k, fs, w) in the following equations. The virtualreceiving array correlation vector h(k, fs, w) includes as many elementsas Nt×Na, which is the product of the number of transmitting antennas Ntand the number of receiving antennas Na. The virtual receiving arraycorrelation vector h(k, fs, w) is used in the following description of aprocess of making a direction estimate based on a phase differencebetween receiving antennas 202 in response to reflected-wave signalsfrom a target. Note here that z=1, . . . , Nt and b=1, Na.

$\begin{matrix}{{h\left( {k,{fs},w} \right)} = {\begin{bmatrix}{{FT\_ CI}_{(1)}^{1}\left( {k,{fs},w} \right)} \\{{FT\_ CI}_{(2)}^{1}\left( {k,{fs},w} \right)} \\\vdots \\{{FT\_ CI}_{({Nt})}^{1}\left( {k,{fs},w} \right)} \\{{FT\_ CI}_{(1)}^{2}\left( {k,{fs},w} \right)} \\{{FT\_ CI}_{(2)}^{2}\left( {k,{fs},w} \right)} \\\vdots \\{{FT\_ CI}_{({Nt})}^{2}\left( {k,{fs},w} \right)} \\\vdots \\{{FT\_ CI}_{(1)}^{Na}\left( {k,{fs},w} \right)} \\{{FT\_ CI}_{(2)}^{Na}\left( {k,{fs},w} \right)} \\\vdots \\{{FT\_ CI}_{({Nt})}^{Na}\left( {k,{fs},w} \right)}\end{bmatrix} = \begin{bmatrix}{h^{1}\left( {k,{fs},w} \right)} \\{h^{2}\left( {k,{fs},w} \right)} \\\vdots \\{h^{Na}\left( {k,{fs},w} \right)}\end{bmatrix}}} & (4) \\{{h^{b}\left( {k,{fs},w} \right)} = \begin{bmatrix}{{FT\_ CI}_{(1)}^{b}\left( {k,{fs},w} \right)} \\{{FT\_ CI}_{(2)}^{b}\left( {k,{fs},w} \right)} \\\vdots \\{{FT\_ CI}_{({Nt})}^{b}\left( {k,{fs},w} \right)}\end{bmatrix}} & (5)\end{matrix}$

The foregoing has described processes in the components of the signalprocessor 207.

The direction estimator 214 calculates a virtual receiving arraycorrelation vector h_(_after_cal)(k, fs, w) with corrections made to aphase deviation and an amplitude deviation between antenna systemprocessors 201 with use of an array correction value h_cal_([y]) for thevirtual receiving array correlation vector h(k, fs, w) of the wthDoppler frequency analyzer 213 outputted from the antenna systemprocessors 201-1 to 201-Na. The virtual receiving array correlationvector h_(_after_cal)(k, fs, w) is expressed by the following equation.It should be noted that y=1, (Nt×Na).

$\begin{matrix}{{{h_{\_ \; {after}\; \_ \; {cal}}\left( {k,{fs},w} \right)} = {{{CA}\mspace{11mu} {h\left( {k,{fs},w} \right)}} = \begin{bmatrix}{h_{1}\left( {k,{fs},w} \right)} \\{h_{2}\left( {k,{fs},w} \right)} \\\vdots \\{h_{{Na} \times {Nr}}\left( {k,{fs},w} \right)}\end{bmatrix}}}{{CA} = \begin{bmatrix}{h\_ cal}_{\lbrack 1\rbrack} & 0 & \ldots & 0 \\0 & {h\_ cal}_{\lbrack 2\rbrack} & \ddots & \ldots \\\vdots & \ddots & \ddots & 0 \\0 & \ldots & 0 & {h\_ cal}_{\lbrack{{Nt} \times {Na}}\rbrack}\end{bmatrix}}} & (6)\end{matrix}$

The virtual receiving array correlation vector h_(_after_cal)(k, fs, w)with corrections made to the inter-antenna deviations is a column vectorcomposed of Na×Nr elements. In the following, the elements of thevirtual receiving array correlation vector h_(_after_cal)(k, fs, w) aredenoted as h₁(k, fs, w), . . . , h_(Na×Nr)(k, fs, w) for use in thedescription of the direction estimation process.

Antenna Arrangement in Radar Apparatus 10

Arrangements of the Nt transmitting antennas 106 and the Na receivingantennas 202 in the radar apparatus 10 thus configured are described.

The Nt transmitting antennas 106 (transmitting array antenna) include a“first antenna group” including a plurality of transmitting antennas 106that are identical in position in a vertical direction (called verticalposition) and different in position in a horizontal direction (calledhorizontal position) (i.e. a plurality of transmitting antennas 106arranged in a horizontal direction) and a “second antenna” that is atransmitting antenna 106 placed in a position different from thevertical and horizontal positions of the plurality of transmittingantennas 106 of the first antenna group.

Further, the Na receiving antennas 202 (receiving array antenna) includea “third antenna group” including a plurality of receiving antennas 202that are identical in vertical position and different in horizontalposition (i.e. a plurality of receiving antennas 202 arranged in ahorizontal direction) and a “fourth antenna” that is a receiving antenna202 placed in a position different from the vertical and horizontalpositions of the plurality of receiving antennas 202 of the thirdantenna group.

The following describes example arrangements of transmitting andreceiving antennas according to Embodiment 1.

FIG. 8A shows an example arrangement of transmitting antennas 106 andreceiving antennas 202. Further, FIG. 8B shows an arrangement of avirtual receiving array that is obtained by the antenna arrangementshown in FIG. 8A.

(1) Arrangement of Transmitting and Receiving Antennas

FIG. 8A assumes that the number Nt of transmitting antennas 106 is 3 andthe number Na of receiving antennas 202 is 4. Further, the threetransmitting antennas 106 are denoted by Tx #1 to Tx #3, and the fourreceiving antennas 202 are denoted by Rx #1 to Rx #4.

In FIG. 8A, the receiving antennas Rx #1 to Rx #3 constitute a thirdantenna group of receiving antennas that are identical in verticalposition and different in horizontal position. Specifically, in FIG. 8A,the horizontal interelement spacings D_(RH) between the receivingantennas Rx #1 to Rx #3 of the third antenna group are constant (regularspacings).

Further, in FIG. 8A, the receiving antenna Rx #4 is a fourth antennaplaced in a position different from both the horizontal and verticalpositions in which the third antenna group is placed. Specifically, inFIG. 8A, the horizontal position of the receiving antenna Rx #4, whichis the fourth antenna, is a position that is at a spacing D_(RH) outward(rightward) in a horizontal direction from the horizontal position of areceiving antenna at one end of the third antenna group (the leftmostantenna Rx #1 or the rightmost antenna Rx #3. In the example shown inFIG. 8A, the rightmost antenna Rx #3).

Further, in FIG. 8A, the vertical position of the fourth antenna (Rx #4)is a position that is at a spacing D_(RV) from the vertical position ofthe third antenna group (Rx #1 to Rx #3).

Meanwhile, in FIG. 8A, the transmitting antennas Tx #1 and Tx #2constitute a first antenna group of transmitting antennas that areidentical in vertical position and different in horizontal position.Further, in FIG. 8A, the transmitting antenna Tx #3 is a second antennaplaced in a position different from both the horizontal and verticalpositions in which the first antenna group is placed.

Specifically, in FIG. 8A, the horizontal interelement spacing D_(TH)between the transmitting antennas Tx #1 and Tx #2 of the first antennagroup is a spacing (D_(Z)+D_(RH)) obtained by adding the spacing D_(RH)to the horizontal antenna aperture length D_(Z) of the third antennagroup (Rx #1, Rx #2, and Rx #3). For example, in the interelementspacing D_(TH) of the first antenna group, the spacing D_(RH) that isadded to the antenna aperture length D_(Z) is equal to theaforementioned horizontal spacing between the third antenna group andthe fourth antenna (in FIG. 8A, the spacing D_(RH) between Rx #3 and Rx#4).

Further, in FIG. 8A, the horizontal position of the transmitting antennaTx #3, which is the second antenna, is a position inside thetransmitting antennas Tx #1 and Tx #2 of the first antenna group.Specifically, the horizontal position of the transmitting antenna Tx #3is a position displaced by a spacing D_(T2H) in a horizontal directionwithin the range of horizontal aperture of the first antenna group (inFIG. 8A, within the range inside the horizontal positions of theend-point antennas Tx #1 and Tx #2) from the horizontal position ofeither antenna of the first antenna group (Tx #1 and Tx #2).

For example, as shown in FIG. 8A, in a case where the horizontalposition of the fourth antenna (Rx #4) is on the outer side (right side)of the horizontal position of the rightmost antenna Rx #3 of the thirdantenna group, the interelement spacing between antennas in the thirdantenna group based on the leftmost antenna Rx #1 of the third antennagroup (in the case of FIG. 8A, the spacing D_(RH) between Rx #1 and Rx#2 or the spacing 2D_(RH) between Rx #1 and Rx #3) may be used as thespacing D_(T2H) from the horizontal position of the rightmost antenna Tx#2 of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #4) is on the outer side (left side) of thehorizontal position of the leftmost antenna Rx #1 of the third antennagroup, the interelement spacing between antennas in the third antennagroup based on the rightmost antenna Rx #3 of the third antenna group(for example, in the case of the third antenna group shown in FIG. 8A,the spacing D_(RH) between Rx #3 and Rx #2 or the spacing 2D_(RH)between Rx #3 and Rx #1) may be used as the spacing D_(T2H) from thehorizontal position of the leftmost antenna Tx #1 of the first antennagroup.

That is, the horizontal interelement spacing (in FIG. 8A, D_(RH) or2D_(RH)) between a receiving antenna (in FIG. 8A, Rx #1) of the thirdantenna group (in FIG. 8A, Rx #1 to Rx #3) located at an end on a sideopposite (second side; in FIG. 8A, the left side) to a side (first side;in FIG. 8A, the right side) close to the position in which the fourthantenna (Rx #4) is placed and each of the other antennas (in FIG. 8A, Rx#2 and Rx #3) of the third antenna group is identical to the horizontalinterelement spacing (in FIG. 8A, D_(RH)) between the transmittingantenna Tx #2, of the adjacent transmitting antennas Tx #1 and Tx #2 ofthe first antenna group, that is located on the same side (in FIG. 8A,the right side) as the first side and the transmitting antenna (Tx #3)of the second antenna.

In other words, the horizontal interelement spacing (in FIG. 8A,D_(T2H)=D_(RH)) between a transmitting antenna (in FIG. 8A, therightmost antenna Tx #2), of the transmitting antennas (in FIG. 8A, Tx#1 and Tx #2) of the first antenna group, that is located on a firstside (in FIG. 8A, the right side) and the second antenna (Tx #3) isidentical to the interelement spacing (in FIG. 8A, D_(RH) or 2D_(RH))between a receiving antenna (in FIG. 8A, the leftmost antenna Rx #1) ofthe receiving array antenna located at an end on a side opposite (inFIG. 8A, the left side) to the first side of the first antenna group andeach of the other receiving antennas (in FIG. 8A, Rx #2 and Rx #3).

Further, in FIG. 8A, the vertical position of the second antenna (Tx #3)is a position that is at a spacing DTV from the vertical position of thefirst antenna group (Tx #1 and Tx #2).

Note here that the spacing DTV is a spacing that is different from thevertical spacing D_(RV) between the third antenna group and the fourthantenna. In other words, the spacing DTV and the spacing D_(RV) needonly be set so that in a case where the first antenna group (Tx #1 andTx #2) and the third antenna group (Rx #1, Rx #2, and Rx #3) areidentical (if made to agree) in vertical position with each other, thevertical position (reference position) of the first and third antennagroups, the vertical position of the second antenna, and the verticalposition of the fourth antenna are different positions (i.e. do notoverlap).

As shown in FIG. 8A, the arrangement of the transmitting antennas Tx #1to Tx #3 that constitute the transmitting array antenna is anarrangement in which the antennas do not overlap in a verticaldirection. For this reason, the vertical size of the transmittingantennas Tx #1 to Tx #3 that constitute the transmitting array antennacan be an arbitrary size. Similarly, as shown in FIG. 8A, thearrangement of the receiving antennas Rx #1 to Rx #4 that constitute thereceiving array antenna is an arrangement in which the antennas do notoverlap in a vertical direction. For this reason, the vertical size ofthe receiving antennas Rx #1 to Rx #4 that constitute the receivingarray antenna can be an arbitrary size.

(2) Arrangement of Virtual Receiving Array

The arrangement of the virtual receiving array (virtual antennas VA #1to VA #12) shown in FIG. 8B, which is constituted by the antennaarrangement shown in FIG. 8A described above, has the followingcharacteristics.

Note here that the arrangement of the virtual receiving array can beexpressed by the following equation from the position of a transmittingantenna that constitutes a transmitting array antenna (position of afeeding point) and the position of a receiving antenna that constitutesa receiving array antenna (position of a feeding point). Note here thatmod(x, y) is an operator for calculation of a reminder after division(modulo arithmetic) and returns a remainder of division of x by y.Further, ceil(x) is an operator that returns a value rounded to theclosest integer of not less than x.

$\quad\begin{matrix}\left\{ \begin{matrix}{X_{V\; \_ \; \# \mspace{11mu} k} = {\left( {X_{T\; \_ {\# {\lbrack{{{mod}{({{k - 1},{Nt}})}} + 1}\rbrack}}} - X_{T\; \_ \# \mspace{11mu} 1}} \right) + \left( {X_{R\mspace{11mu} {\# {\lbrack{{ceil}{({k/{Na}})}}\rbrack}}} - X_{R\; \_ \# \mspace{11mu} 1}} \right)}} \\{Y_{V\; \_ \; \# \mspace{11mu} k} = {\left( {Y_{T\; \_ {\# {\lbrack{{{mod}{({{k - 1},{Nt}})}} + 1}\rbrack}}} - Y_{T\; \_ \# \mspace{11mu} 1}} \right) + \left( {Y_{R\mspace{11mu} {\# {\lbrack{{ceil}{({k/{Na}})}}\rbrack}}} - Y_{R\; \_ \# \mspace{11mu} 1}} \right)}}\end{matrix} \right. & (7)\end{matrix}$

Assume here that the position coordinates of a transmitting antenna thatconstitutes the transmitting array antenna is (X_(T_#n), Y_(T_#n))(where n=1, . . . , Nt), that the position coordinates of a receivingantenna that constitutes the receiving array antenna is (X_(R_#m),Y_(R_#m)) (where m=1, Na), and that the position coordinates of avirtual antenna that constitutes a virtual receiving array antenna is(X_(V_#k), Y_(V_#k)) (where k=1, . . . , Nt×Na). It should be noted thatEq. (7) expresses VA #1 as a position reference (0, 0) of the virtualreceiving array.

The virtual receiving array shown in FIG. 8B is configured to include ahorizontal virtual linear array antenna HLA composed of six virtualantennas (VA #1, VA #4, VA #7, VA #2, VA #5, and VA #8 surrounded bydashed lines shown in FIG. 8B) arranged in a straight line atinterelement spacings D_(RH) (regular spacings) in a horizontaldirection. The HLA shown in FIG. 8B is obtained from a horizontalpositional relationship between the two transmitting antennas Tx #1 andTX #2 of the first antenna group placed at an interelement spacingD_(TH) in a horizontal direction in FIG. 8A and the three receivingantennas Rx #1, Rx #2, and Rx #3 of the third antenna group placed atinterelement spacings D_(RH) in a horizontal direction in FIG. 8A.Specifically, the number of virtual antennas that are lined up in astraight line in a horizontal direction has such a relationship as to bethe product (in FIG. 8B, 6) of the number of antennas (in FIG. 8A, 2) ofthe first antenna group and the number of antennas (in FIG. 8A, 3) ofthe third antenna group.

Further, in FIG. 8A, the interelement spacings D_(RH) between theplurality of receiving antennas (Rx #1 to Rx #3) of the third antennagroup are equal. Further, the interelement spacings (D_(RH)) between theplurality of receiving antennas of the third antenna group and thespacing (D_(RH)) between the third antenna group and the fourth antenna(Rx #4) in a horizontal direction are equal. This causes the six virtualantennas to be placed at regular spacings in a straight line in ahorizontal direction in the HLA of the virtual receiving array shown inFIG. 8B.

Further, the virtual receiving array shown in FIG. 8B is configured toinclude a vertical virtual linear array antenna VLA composed of threevirtual antennas (VA #2, VA #10, and VA #6 surrounded by dashed linesshown in FIG. 8B) arranged in a straight line in a vertical direction.The number of virtual antennas that are lined up in a straight line in avertical direction has such a relationship as to be “(Number of Antennasof Second Antenna)+(Number of Antennas of Fourth Antenna)+1” (in FIG.8B, 3).

The VLA has an arrangement of virtual antennas lined up in ascendingorder of D_(TV) and D_(RV) from the vertical position of the firstantenna group (Tx #1 and Tx #2). For example, in a case whereD_(TV)>D_(RV), the interelement spacings between the virtual antennaswithin the VLA are D_(RV) and (D_(TV)−D_(RV)). Further, in a case whereD_(TV)<D_(RV), the interelement spacings between the virtual antennaswithin the VLA are D_(TV) and (D_(RV)−D_(TV)).

Further, when D_(TV)=2D_(RV), the VLA has an arrangement of virtualantennas lined up in a straight line in a vertical direction at regularspacings (D_(RV)). Further, when 2D_(TV)=D_(RV), the VLA has anarrangement of virtual antennas lined up in a straight line in avertical direction at regular spacings (D_(TV)).

FIG. 8B shows, as an example, an example where D_(TV)=2D_(RV) (i.e. acase where D_(TV)>D_(RV)). That is, in FIG. 8B, the VLA has anarrangement of VA #2, VA #10, and VA #6 lined up in a straight line in avertical direction at regular spacings (D_(RV)). This makes it possibleto reduce a peak side lobe ratio in a vertical direction.

It should be noted that neither D_(TV)=2D_(RV) nor 2D_(TV)=D_(RV) isintended to impose any limitation. That is, in a case where it isassumed that the first antenna group and the third antenna group areidentical in position in a vertical direction, the interelement spacingsbetween vertically adjacent antennas in the first antenna group (Tx #1and TX #2) (or the third antenna group (Rx #1 to Rx #3)), the secondantenna (Tx #3), and the fourth antenna (Rx #4) may be equal spacings orunequal spacings. In the case of unequal spacings (in a case other thanD_(TV)=2D_(RV) or 2D_(TV)=D_(RV)), the VLA is an unequally-spaced arrayand can have an enlarged aperture length. This brings about a narrowermain lobe and an effect of improving vertical angular separationperformance.

Note here that, as shown in Eq. (4), Eq. (7), and FIG. 8B, the virtualantenna VA #1 is obtained from a relationship between the receivingantenna Rx #1 and the transmitting antenna Tx #1. Further, with theposition (vertical position, horizontal position) of VA #1 as thereference position (0, 0), the virtual antenna VA #2 of the VLA isobtained from a relationship between the receiving antenna Rx #1 and thetransmitting antenna Tx #2, the virtual antenna VA #6 of the VLA isobtained from a relationship between the receiving antenna Rx #2 and thetransmitting antenna Tx #3, and the virtual antenna VA #10 of the VLA isobtained from a relationship between the receiving antenna Rx #4 and thetransmitting antenna Tx #1.

As mentioned above, the interelement spacing D_(TH) of the first antennagroup is equal to the sum of the aperture length D_(Z) of the thirdantenna group and the spacing D_(RH) between the third antenna group andthe fourth antenna in a horizontal direction, i.e. the horizontalaperture length of the receiving array antenna. As a result, thehorizontal position of VA #2 (virtual antenna obtained from therelationship between Rx #1 and Tx #2) placed in a position that is atthe interelement spacing D_(TH) of the first antenna group in ahorizontal direction from the reference position VA #1 and thehorizontal position of VA #10 (virtual antenna obtained from therelationship between Rx #4 and Tx #1) placed in a position that is atthe aperture length (D_(Z)+D_(RH)) of the receiving array antenna in ahorizontal direction from the reference position VA #1 become identical(in FIG. 8B, a position that is at a spacing 3D_(RH) from the referenceposition). Further, since the third antenna group and the fourth antennaare different in vertical position by D_(RH), VA #2 and VA #10 are alsodifferent in vertical position by D_(RV). As a result, VA #2 and VA #10are placed in an identical horizontal position and lined up side by sidein a vertical direction.

Further, the interelement spacing D_(T2H) between the right end (in FIG.8A, Tx #2) of the first antenna group and the second antenna (Tx #3) ina horizontal direction is equal to the interelement spacing D_(RH) fromthe leftmost antenna Rx #1 of the third antenna group to anotherreceiving antenna (e.g. Rx #2) of the third antenna group. As a result,the horizontal position of the virtual antenna VA #2 obtained from therelationship between Rx #1 and Tx #2 and the horizontal position of thevirtual antenna VA #6 obtained from the relationship between Rx #2 andTx #3 become identical (in FIG. 8B, a position that is at a spacing3D_(RH) from the reference position). Further, since the first antennagroup and the second antenna are different in vertical position, VA #2and VA #6 are also different in vertical position by D_(TV). As aresult, VA #2 and VA #6 are placed in an identical horizontal positionand lined up side by side in a vertical direction.

Further, the reference position (i.e. the vertical position of the firstantenna group and the vertical position of the third antenna group), theposition (spacing D_(TV)) of the second antenna, and the position(spacing D_(RV)) of the fourth antenna are different in a verticaldirection. As a result, the virtual receiving array has its VA #2 placedin a reference position in a vertical direction and has its VA #10 andVA #6 placed in different vertical positions.

Thus, VA #2, VA #10, and VA #6, which constitute the VLA, are placed inan identical horizontal position and different vertical positions.

In this way, with the limited number Nt of transmitting antennas being 3and the limited number Na of receiving antennas being 4, the arrangementof antennas that constitute a transmitting array antenna and a receivingarray antenna shown in FIG. 8A allows the arrangement of the virtualreceiving array (VA #1, . . . , VA #12) shown in FIG. 8B to be anarrangement of six antennas (HLA) in a straight line in a horizontaldirection and three antennas (VLA) in a straight line in a verticaldirection, thus making it possible to maximally enlarge the aperturelengths of the virtual receiving array.

The direction estimator 214 performs horizontal and verticaldirection-of-arrival estimation processes in the following manner withuse of signals received by a virtual receiving array (see FIG. 8B)obtained from the aforementioned arrangement of transmitting andreceiving antennas (see FIG. 8A).

The element numbers (numbers of VA #) of the virtual receiving arraycorrespond to the element numbers of a column vector of the virtualreceiving array correlation vector h_(_after_cal)(k, fs, w) of Eq. (6)with corrections made to the inter-antenna deviations. For example, VA#1 corresponds to the first element h₁(k, fs, w) of the column vectorelement of h_(_after_cal)(k, fs, w). The same applies to VA #2 to VA#12.

In the horizontal and vertical direction-of-arrival estimation, thedirection estimator 214 calculates a spatial profile with variations inazimuth direction θ and elevation direction ϕ in a direction estimationevaluation function value P(θ, ϕ, fs, w) within a predetermined angularrange, extracts a predetermined number of maximal peaks of thecalculated spatial profile in descending order, and outputs the azimuthand elevation directions of the maximal peaks as direction-of-arrivalestimate values.

It should be noted that the direction estimation evaluation functionvalue P(θ, ϕ, fs, w) can be obtained by various methods depending ondirection-of-arrival estimation algorithms. For example, a usableexample of a method for estimation with an array antenna is disclosed inDirection-of-arrival estimation using signal subspace modeling Cadzow,J. A.; Aerospace and Electronic Systems, IEEE Transactions on Volume:28, Issue: 1 Publication Year: 1992, Page(s): 64-79.

For example, a beamformer method can be expressed by equations below.Other techniques such as Capon and MUSIC are similarly applicable.

P(θ_(u)ϕ_(v) k,fs,w)=a|(θ_(u),ϕ_(v))^(H) h _(_after_cal)(k,fs,w)|²   (8)

Note here that the superscript H is the Hermitian transposed operator.Further, a(θ_(u), ϕ_(v)) denotes the directional vector of the virtualreceiving array with respect to an incoming wave in the azimuthdirection θ and the elevation direction ϕ.

As noted above, the direction estimator 214 outputs, as radarmeasurement results, the direction-of-arrival estimate values thuscalculated and the discrete time k and Doppler frequency fsΔΦ at whichthe direction-of-arrival estimate values were calculated.

Further, the azimuth direction θ_(u) is a vector obtained by changing,by a predetermined azimuth interval β₁, an azimuth range within which adirection-of-arrival estimate is made. For example, θ_(u) is set asfollows:

θ_(u)=θ min+uβ ₁ , u=0, . . . , NU

NU=floor[θ max−θ min)/β₁]+1

where floor (x) is a function that returns the a maximum integer valuethat does not exceed the real number x.

Further, ϕ_(v) is obtained by changing, by a predetermined azimuthinterval β₂, an elevation range within which a direction-of-arrivalestimate is made. For example, ϕ_(v) is set as follows:

ϕ_(v)=ϕ min+vβ ₂ , v=0, . . . , NV

NV=floor[(ϕ max−ϕ min)/β₂]+1

In Embodiment 1, the directional vector a(θ_(u), ϕ_(v)) of the virtualreceiving array is calculated in advance on the basis of the virtualreceiving array arrangement VA #1, . . . , VA #(Nt×Na). Note here thatthe directional vector a(θ_(u), ϕ_(v)) is a (Nt×Na)th column vectorwhose element is a complex response of the virtual receiving array inthe case of arrival of radar reflected waves from the azimuth directionθ and the elevation direction (I). Further, the complex responsea(θ_(u), ϕ_(v)) of the virtual receiving array represents a phasedifference that is geometrical-optically calculated at the interelementspacing between antennas.

Further, the aforementioned time information k may be converted intodistance information to be outputted. The time information k may beconverted into distance information R(k) according to equation below.Note here that Tw denotes the code transmission section, L denotes thepulse code length, and C₀ denotes the velocity of light.

$\begin{matrix}{{R(k)} = {k\frac{T_{w}C_{0}}{2L}}} & (9)\end{matrix}$

Further, the Doppler frequency information (fsΔΦ) may be converted intoa relative velocity component to be outputted. The Doppler frequencyfsΔΦ can be converted into a relative velocity component v_(d)(fs)according to equation below. Note here that X is the wavelength of thecarrier frequency of an RF signal that is outputted from a radiotransmitter 105.

$\begin{matrix}{{v_{d}\left( f_{s} \right)} = {\frac{\lambda}{2}f_{s}\Delta \theta}} & (10)\end{matrix}$

As noted above, using the array arrangement shown in FIG. 8A preventsantennas from overlapping in a vertical direction in the radar apparatus10 (MIMO radar), thus making it possible to use sub-array antennas of anarbitrary size in a vertical direction. Further, using the arrayarrangement shown in FIG. 8A makes it possible to maximize an apertureplane constituted by the horizontal and vertical directions of thevirtual receiving array shown in FIG. 8B.

Therefore, according to Embodiment 1, the radar apparatus 10 canmaximally enlarge the vertical and horizontal aperture lengths of avirtual receiving array in performing two-dimensional vertical andhorizontal beam scanning with use of a MIMO radar, thus allowinghigh-resolution angle measuring in vertical and horizontal directions.That is, Embodiment 1 makes it possible to maximally enlarge thevertical and horizontal aperture lengths of a virtual receiving arraywithout deterioration in detection performance of a radar apparatus andimprove angular resolution with a small number of antenna elements.

In FIG. 8A, the spacings between the transmitting antennas Tx #1 to Tx#3 and the receiving antennas Rx #1 to Rx #4 do not affect thearrangement of the virtual receiving array. Note, however, that sincethe proximity of the transmitting antennas Tx #1 to Tx #3 and thereceiving antennas Rx #1 to Rx #4 enhances the degree of couplingbetween the transmitting and receiving antennas, it is preferable thatthey be arranged as far from one another as possible within theallowable antenna size. The same applies to the after-mentioned otherantenna arrangements.

Further, in FIG. 8A, the vertical position of the second antenna (Tx #3)is a position that is at a spacing D_(TV) downward from the verticalposition of the first antenna group (Tx #1 and Tx #2), and the verticalposition of the fourth antenna (Rx #4) is a position that is at aspacing D_(RV) downward from the vertical position of the third antennagroup (Rx #1, Rx #2, and Rx #3). However, in Embodiment 1, the verticalposition of the second antenna (Tx #3) may be a position that is at aspacing D_(TV) upward from the vertical position of the first antennagroup (Tx #1 and Tx #2), and the vertical position of the fourth antenna(Rx #4) is a position that is at a spacing D_(RV) upward from thevertical position of the third antenna group (Rx #1, Rx #2, and Rx #3).

Further, although Embodiment 1 has been described by taking, as anexample, a case where the number Nt of transmitting antennas is 3 andthe number Na of receiving antennas is 4, the number Na of receivingantennas is not limited to 4. For example, the first antenna group needsonly include at least two transmitting antennas 106, and the thirdantenna group needs only include at least two receiving antennas 202.Therefore, it is possible to arrange a virtual receiving antenna in amanner similar to Embodiment 1 and bring about effects which are similarto those of Embodiment 1, provided the number of transmitting antennasof the first antenna group is 2 or larger and the number of receivingantennas of the third antenna group is 2 or larger. That is, the minimumantenna configuration in Embodiment 1 is such that the number Nt oftransmitting antennas is 3 and the number Na of receiving antennas is 3.Similarly, as for the after-mentioned other antenna arrangements, too,the minimum antenna configuration is such that the number Nt oftransmitting antennas is 3 and the number Na of receiving antennas is 3.

For example, the number of virtual antennas that constitute the HLA inthe virtual receiving array corresponds to the product of the number oftransmitting antennas of the first antenna group and the number ofreceiving antennas of the third antenna group. Therefore, the larger thenumber of transmitting antennas of the first antenna group or the numberof receiving antennas of the third antenna group becomes, the larger thenumber of virtual antennas that constitute the HLA becomes. This bringsabout a narrower horizontal main lobe and an effect of improvinghorizontal angular separation performance.

As an example, FIG. 9A shows an arrangement in which the minimum antennaconfiguration is such that the number Nt of transmitting antennas is 3(Tx #1, Tx #2, and Tx #3) and the number Na of receiving antennas is 3(Rx #1, Rx #2, and Rx #3), and FIG. 9B shows an arrangement of a virtualreceiving array that is obtained by the antenna arrangement shown inFIG. 9A.

In FIG. 9A, the transmitting array antenna is composed of a firstantenna group including a plurality of transmitting antennas (Tx #1 andTx #2) that are identical in vertical position and different inhorizontal position and a second antenna (Tx #3) placed in a positiondifferent from the vertical and horizontal positions of the transmittingantennas of the first antenna group.

Further, the receiving array antenna is composed of a third antennagroup including a plurality of antennas (Rx #1 and Rx #2) that areidentical in vertical position and different in horizontal position anda fourth antenna (Rx #3) placed in a position different from thevertical and horizontal positions of the antennas of the third antennagroup.

Assume here that D_(RH) is the horizontal interelement spacing betweenthe plurality of antennas (Rx #1 and Rx #2) of the third antenna groupand that the horizontal position of the fourth antenna (Rx #3) is aposition that is at a spacing D_(RH) outward (rightward) in a horizontaldirection from the horizontal position of a receiving antenna at one endof the third antenna group (the leftmost antenna Rx #1 or the rightmostantenna Rx #2. In the example shown in FIG. 9A, the rightmost antenna Rx#2).

Further, in FIG. 9A, the horizontal interelement spacing D_(TH) of thefirst antenna group (Tx #1 and Tx #2) is a spacing (D_(TH)=D_(Z)+D_(RH))obtained by adding together the horizontal antenna aperture length D_(Z)of the third antenna group (Rx #1 and Rx #2) and the spacing D_(RH).

Further, the horizontal position of the second antenna (Tx #3) is aposition displaced by a spacing D_(T2H) in a horizontal direction withinthe range of horizontal aperture of the first antenna group (in FIG. 9A,within the range inside the horizontal positions of the end-pointantennas Tx #1 and Tx #2) from the horizontal position of either antennaof the first antenna group (Tx #1 and Tx #2).

For example, as shown in FIG. 9A, in a case where the horizontalposition of the fourth antenna (Rx #3) is on the outer side (right side)of the horizontal position of the rightmost antenna Rx #2 of the thirdantenna group, the interelement spacing between antennas in the thirdantenna group based on the leftmost antenna Rx #1 of the third antennagroup (in the case of FIG. 9A, the spacing D_(RH) between Rx #1 and Rx#2) may be used as the spacing from the horizontal position of therightmost antenna Tx #2 of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #3) is on the outer side (left side) of thehorizontal position of the leftmost antenna Rx #1 of the third antennagroup, the interelement spacing between antennas in the third antennagroup based on the rightmost antenna Rx #2 of the third antenna group(in the case of the third antenna group shown in FIG. 9A, D_(RH)) may beused as the spacing D_(T2H) from the horizontal position of the leftmostantenna Tx #1 of the first antenna group.

Further, in FIG. 9A, the vertical position of the second antenna (Tx #3)is a position that is at a spacing D_(TV) from the vertical position ofthe first antenna group (Tx #1 and Tx #2), and the vertical position ofthe fourth antenna (Rx #3) is a position that is at a spacing D_(RV),which is different from the spacing D_(TV), from the vertical positionof the third antenna group (Rx #1 and Rx #2).

The arrangement of the virtual receiving array (virtual antennas VA #1to VA #9) shown in FIG. 9B, which is constituted by the antennaarrangement shown in FIG. 9A described above, has the followingcharacteristics.

The virtual receiving array shown in FIG. 9B is configured to include ahorizontal virtual linear array antenna HLA composed of four virtualantennas (VA #1, VA #4, VA #2, and VA #5) arranged in a straight line atinterelement spacings D_(RH) (regular spacings) in a horizontaldirection. Further, the virtual receiving array shown in FIG. 9B isconfigured to include a vertical virtual linear array antenna VLAcomposed of three virtual antennas (VA #2, VA #7, and VA #6) arranged ina straight line in a vertical direction.

As shown in FIG. 9A, the arrangement of the transmitting antennas Tx #1to Tx #3 that constitute the transmitting array antenna is anarrangement in which the antennas do not overlap in a verticaldirection. For this reason, the vertical size of the transmittingantennas Tx #1 to Tx #3 that constitute the transmitting array antennacan be an arbitrary size. Similarly, as shown in FIG. 9A, thearrangement of the receiving antennas Rx #1 to Rx #3 that constitute thereceiving array antenna is an arrangement in which the antennas do notoverlap in a vertical direction. For this reason, the vertical size ofthe receiving antennas Rx #1 to Rx #3 that constitute the receivingarray antenna can be an arbitrary size.

Furthermore, with the limited number Nt of transmitting antennas being 3and the limited number Na of receiving antennas being 3, the arrangementof antennas that constitute a transmitting array antenna and a receivingarray antenna shown in FIG. 9A allows the arrangement of the virtualreceiving array (VA #1, . . . , VA #9) shown in FIG. 9B to be anarrangement of four antennas (HLA) in a straight line in a horizontaldirection and three antennas (VLA) in a straight line in a verticaldirection, thus making it possible to maximally enlarge the aperturelengths of the virtual receiving array.

Variation 1 of Embodiment 1

FIG. 8A or 9A has shown a case where there is agreement between thedirection (downward) in which the vertical position of the secondantenna is placed with respect to the vertical position of the firstantenna group and the direction (downward) in which the verticalposition of the fourth antenna is placed with respect to the verticalposition of the third antenna group. However, there does not need to beagreement between the direction in which the vertical position of thesecond antenna is placed with respect to the vertical position of thefirst antenna group and the direction in which the vertical position ofthe fourth antenna is placed with respect to the vertical position ofthe third antenna group. The same applies to the after-mentioned otherantenna arrangements.

FIG. 10A shows an example arrangement of transmitting antennas 106 andreceiving antennas 202 according to Variation 1 of Embodiment 1.Further, FIG. 10B shows an arrangement of a virtual receiving array thatis obtained by the antenna arrangement shown in FIG. 10A.

As with FIG. 8A, FIG. 10A assumes that the number Nt of transmittingantennas 106 is 3 and the number Na of receiving antennas 202 is 4.Further, the three transmitting antennas 106 are denoted by Tx #1 to Tx#3, and the four receiving antennas 202 are denoted by Rx #1 to Rx #4.

Further, in FIG. 10A, as in FIG. 8A, the horizontal interelementspacings D_(RH) between the receiving antennas Rx #1 to Rx #3 of thethird antenna group are constant (regular spacings), and the horizontalposition of the receiving antenna Rx #4, which is the fourth antenna, isa position that is at a spacing D_(RH) outward (rightward) in ahorizontal direction from the horizontal position of a receiving antennaat one end of the third antenna group (the leftmost antenna Rx #1 or therightmost antenna Rx #3. In the example shown in FIG. 10A, the rightmostantenna Rx #3).

Further, in FIG. 10A, as in FIG. 8A, the horizontal interelement spacingD_(TH) between the transmitting antennas Tx #1 and Tx #2 of the firstantenna group is a spacing (D_(Z)+D_(RH)) obtained by adding the spacingD_(RH) to the horizontal antenna aperture length D_(Z) of the thirdantenna group (Rx #1, Rx #2, and Rx #3), and the horizontal position ofthe transmitting antenna Tx #3, which is the second antenna, is aposition that is at a spacing D_(T2H)=D_(RH) inward in a horizontaldirection from the horizontal position of a transmitting antenna at oneend of the first antenna group (Tx #1 or Tx #2. In the example shown inFIG. 10A, Tx #2).

Further, in FIG. 10A, the vertical position of the second antenna (Tx#3) is a position that is at a spacing D_(TV) downward from the verticalposition of the first antenna group (Tx #1 and Tx #2). Meanwhile, inFIG. 10A, the vertical position of the fourth antenna (Rx #4) is aposition that is at a spacing D_(RV) upward from the vertical positionof the third antenna group (Rx #1, Rx #2, and Rx #3). That is, thedirection in which the vertical position of the second antenna is placedwith respect to the vertical position of the first antenna group and thedirection in which the vertical position of the fourth antenna is placedwith respect to the vertical position of the third antenna group aredifferent.

For example, in FIG. 10A, D_(TV)=D_(RV). Assume here that, in FIG. 10A,an upward direction and a downward direction from the vertical positionof the first antenna group (Tx #1 and Tx #2) are a “positive direction”and a negative direction”, respectively. Similarly, assume that, in FIG.10A, an upward direction and a downward direction from the verticalposition of the third antenna group (Rx #1 to Rx #3) are a “positivedirection” and a negative direction”, respectively. In this case, inFIG. 10A, the second antenna (Tx #3) is placed in a position that is ata spacing D_(TV) in the negative direction from the first antenna group,and the fourth antenna (Rx #4) is placed in a position that is at aspacing D_(RV) in the positive direction from the third antenna group.That is, even if D_(TV)=D_(RV), the spacing D_(TV) and the spacingD_(RV) are deemed as different spacings, as the positive direction andthe negative direction are different.

Further, without being limited to D_(TV)=D_(RV), the spacing D_(TV) andthe spacing D_(RV) need only be set so that in a case where the firstantenna group (Tx #1 and Tx #2) and the third antenna group (Rx #1, Rx#2, and Rx #3) are identical (if made to agree) in vertical positionwith each other, the vertical position (reference position) of the firstand third antenna groups, the vertical position of the second antenna,and the vertical position of the fourth antenna are different positions(i.e. do not overlap).

In this case, too, as in FIG. 8B, the virtual receiving array shown inFIG. 10B is configured to include an HLA composed of six virtualantennas (VA #1, VA #4, VA #7, VA #2, VA #5, and VA #8 surrounded bydashed lines shown in FIG. 10B) arranged in a straight line atinterelement spacings D_(RH) (regular spacings) in a horizontaldirection. Further, as in FIG. 8B, the virtual receiving array shown inFIG. 10B is configured to include a VLA composed of three virtualantennas (VA #2, VA #10, and VA #6 surrounded by dashed lines shown inFIG. 10B) arranged in a straight line in a vertical direction.

It should be noted that FIG. 10B shows VA #12 in parentheses, as VA #8and VA #12 are placed in an identical position. In the after-mentionedother antenna arrangements, too, virtual antennas placed overlappinglyin an identical position in an arrangement of a virtual receiving arrayare shown in parentheses.

Further, when D_(TV)=D_(RV), the VLA shown in FIG. 10B has anarrangement of virtual antennas lined up in a straight line in avertical direction at regular spacings (D_(RV)). Further, when2D_(TV)=D_(RV), the VLA has an arrangement of virtual antennas lined upin a straight line in a vertical direction at irregular spacings (notillustrated).

Even such an antenna arrangement according to Variation 1 of Embodiment1 can bring about effects which are similar to those of Embodiment 1.Variation 2 of Embodiment 1

FIG. 8B has described a configuration including an HLA composed of sixvirtual antennas (VA #1, VA #4, VA #7, VA #2, VA #5, and VA #8) arrangedin a straight line at interelement regular spacings (D_(RH)) in ahorizontal direction. However, the HLA is not limited to a case of beingcomposed of virtual antennas placed at regular spacings but may becomposed of virtual antennas placed at irregular spacings.

FIG. 11A shows an example arrangement of transmitting antennas 106 andreceiving antennas 202 according to Variation 2 of Embodiment 1.Further, FIG. 11B shows an arrangement of a virtual receiving array thatis obtained by the antenna arrangement shown in FIG. 11A.

As with FIG. 8A, FIG. 11A assumes that the number Nt of transmittingantennas 106 is 3 and the number Na of receiving antennas 202 is 4.Further, the three transmitting antennas 106 are denoted by Tx #1 to Tx#3, and the four receiving antennas 202 are denoted by Rx #1 to Rx #4.

In FIG. 11A, as in FIG. 8A, the horizontal interelement spacings D_(RH)between the receiving antennas Rx #1 to Rx #3 of the third antenna groupare constant (regular spacings). Meanwhile, FIG. 11A assumes that thehorizontal position of the receiving antenna Rx #4, which is the fourthantenna, is a position that is at a spacing D_(H) outward (rightward) ina horizontal direction from the horizontal position of a receivingantenna at one end of the third antenna group (the leftmost antenna Rx#1 or the rightmost antenna Rx #3. In the example shown in FIG. 11A, therightmost antenna Rx #3). Note here that the interelement spacing D_(H)is a different value from the spacing D_(RH).

Further, in FIG. 11A, as in FIG. 8A, the horizontal position of thesecond antenna Tx #3, which is the second antenna, is a positiondisplaced by a spacing D_(T2H) inward in a horizontal direction withinthe range of horizontal aperture of the first antenna group (in FIG.11A, within the range inside the horizontal positions of the end-pointantennas Tx #1 and Tx #2) from the horizontal position of either antennaof the first antenna group (Tx #1 and Tx #2).

For example, as shown in FIG. 11A, in a case where the horizontalposition of the fourth antenna (Rx #4) is on the outer side (right side)of the horizontal position of the rightmost antenna Rx #3 of the thirdantenna group, the interelement spacing between antennas in the thirdantenna group based on the leftmost antenna Rx #1 of the third antennagroup (in the case of FIG. 11A, the spacing D_(RH) between Rx #1 and Rx#2 or the spacing 2D_(RH) between Rx #1 and Rx #3) may be used as thespacing D_(T2H) from the horizontal position of the rightmost antenna Tx#2 of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #4) is on the outer side (left side) of thehorizontal position of the leftmost antenna Rx #1 of the third antennagroup, the interelement spacing between antennas in the third antennagroup based on the rightmost antenna Rx #3 of the third antenna group(for example, in the case of the third antenna group shown in FIG. 11A,the spacing D_(RH) between Rx #3 and Rx #2 or the spacing 2D_(RH)between Rx #3 and Rx #1) may be used as the spacing D_(T2H) from thehorizontal position of the leftmost antenna Tx #1 of the first antennagroup.

Further, in FIG. 11A, the horizontal interelement spacing D_(TH) betweenthe transmitting antennas Tx #1 and Tx #2 of the first antenna group isa spacing (D_(Z)+D_(H)) obtained by adding the horizontal spacing(D_(H)) between the third antenna group and the fourth antenna to thehorizontal antenna aperture length D_(Z) of the third antenna group (Rx#1, Rx #2, and Rx #3).

Further, in FIG. 11A, the vertical position of the fourth antenna (Tx#4) is a position that is at a spacing D_(RV) from the vertical positionof the third antenna group (Rx #1 to Rx #3), and the vertical positionof the second antenna (Tx #3) is a position that is at a spacing D_(TV)from the vertical position of the first antenna group (Tx #1 and Tx #2).Note here that, as mentioned above, the spacing D_(TV) and the spacingD_(RV) need only be set so that in a case where the first antenna group(Tx #1 and Tx #2) and the third antenna group (Rx #1, Rx #2, and Rx #3)are identical (if made to agree) in vertical position with each other,the vertical position (reference position) of the first and thirdantenna groups, the vertical position of the second antenna, and thevertical position of the fourth antenna are different positions (i.e. donot overlap).

FIG. 11B shows, as an example, an arrangement of a virtual receivingarray in which D_(H)=1.5D_(RH) and D_(TV)=2D_(RV) in FIG. 11A. It shouldbe noted that the relationship between D_(H) and D_(RH) and therelationship between D_(TV) and D_(RV) are not limited to these.

In the virtual receiving array shown in FIG. 11B, the HLA has anarrangement of six virtual antennas (VA #1, VA #4, VA #7, VA #2, VA #5,and VA #8 surrounded by dashed lines shown in FIG. 11B) in a straightline at irregular spacings (D_(H) and D_(RH)) in a horizontal direction.Further, as in FIG. 8B, the VLA shown in FIG. 11B has an arrangement ofthree virtual antennas (VA #2, VA #10, and VA #6 surrounded by dashedlines shown in FIG. 11B) arranged in a straight line at regular spacings(D_(RV)) in a vertical direction.

Note here that in a case where D_(H)=D_(RH), the HLA has its virtualantennas lined up at regular spacings (D_(RH)) as in FIG. 8B. This makesit possible to reduce the peak side lobe ratio.

Meanwhile, when D_(H)>D_(RH), the HLA has an arrangement of virtualantennas lined up in a straight line at irregular spacings as shown inFIG. 11B, so that the HLA has an enlarged aperture length. For example,the HLA has an enlarged aperture length of 5.5D_(RH) in FIG. 11B,whereas the HLA has an aperture length of 5D_(RH) in FIG. 8B. Thisbrings about a narrower horizontal main lobe and an effect of improvinghorizontal angular separation performance. It should be noted thatenlarging the spacing D_(H) brings about a trade-off between a narrowermain lobe and an increased side lobe level.

Variation 3 of Embodiment 1

Although FIGS. 8A, 10A, and 11A have described cases where thehorizontal interelement spacings between the receiving antennas (Rx #1,Rx #2, and Rx #3) of the third antenna group are constant (D_(RH)), thehorizontal interelement spacings between the receiving antennas (Rx #1,Rx #2, and Rx #3) of the third antenna group may be irregular spacings.In this case, the HLA of the virtual receiving array is composed ofvirtual antennas placed at irregular spacings as in the case ofVariation 2 of Embodiment 1.

FIG. 12A shows an example arrangement of transmitting antennas 106 andreceiving antennas 202 according to Variation 3 of Embodiment 1.Further, FIG. 12B shows an arrangement of a virtual receiving array thatis obtained by the antenna arrangement shown in FIG. 12A.

As with FIG. 8A, FIG. 12A assumes that the number Nt of transmittingantennas 106 is 3 and the number Na of receiving antennas 202 is 4.Further, the three transmitting antennas 106 are denoted by Tx #1 to Tx#3, and the four receiving antennas 202 are denoted by Rx #1 to Rx #4.

FIG. 12A assumes that D_(RH) is the smallest value of the horizontalinterelement spacings between the receiving antennas Rx #1 to Rx #3 ofthe third antenna group. In FIG. 12A, D_(RH) is the interelement spacingbetween the receiving antennas Rx #1 and Rx #2, and 2D_(RH) is theinterelement spacing between the receiving antennas Rx #2 and Rx #3.That is, the interelement spacings between the receiving antennas Rx #1to Rx #3 of the third antenna group are different. It should be notedthat the interelement spacings in the third antenna group are notlimited to these.

Further, FIG. 12A assumes that the horizontal position of the receivingantenna Rx #4, which is the fourth antenna, is a position that is at aspacing D_(H) outward (rightward) in a horizontal direction from thehorizontal position of a receiving antenna at one end of the thirdantenna group (the leftmost antenna Rx #1 or the rightmost antenna Rx#3. In the example shown in FIG. 12A, the rightmost antenna Rx #3). Notehere that the interelement spacing D_(H) may be the same or a differentvalue as or from the spacings (D_(RH) and 2D_(RH)) between the receivingantennas (Rx #1 to Rx #3) of the third antenna group.

Further, in FIG. 12A, the horizontal interelement spacing D_(TH) betweenthe transmitting antennas Tx #1 and Tx #2 of the first antenna group isa spacing (D_(Z)+D_(H)) obtained by adding the horizontal spacing(D_(H)) between the third antenna group and the fourth antenna to thehorizontal antenna aperture length D_(Z) of the third antenna group (Rx#1, Rx #2, and Rx #3).

Further, in FIG. 12A, as in FIG. 8A, the horizontal position of thesecond antenna Tx #3, which is the second antenna, is a positiondisplaced by a spacing D_(T2H) inward in a horizontal direction withinthe range of horizontal aperture of the first antenna group (in FIG.12A, within the range inside the horizontal positions of the end-pointantennas Tx #1 and Tx #2) from the horizontal position of either antennaof the first antenna group (Tx #1 and Tx #2).

For example, as shown in FIG. 12A, in a case where the horizontalposition of the fourth antenna (Rx #4) is on the outer side (right side)of the horizontal position of the rightmost antenna Rx #3 of the thirdantenna group, the interelement spacing between antennas in the thirdantenna group based on the leftmost antenna Rx #1 of the third antennagroup (in the case of FIG. 12A, the spacing D_(RH) between Rx #1 and Rx#2 or the spacing 3D_(RH) between Rx #1 and Rx #3) may be used as thespacing D_(T2H) from the horizontal position of the rightmost antenna Tx#2 of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #4) is on the outer side (left side) of thehorizontal position of the leftmost antenna Rx #1 of the third antennagroup, the interelement spacing between antennas in the third antennagroup based on the rightmost antenna Rx #3 of the third antenna group(for example, in the case of the third antenna group shown in FIG. 12A,the spacing 2D_(RH) between Rx #3 and Rx #2 or the spacing 3D_(RH)between Rx #3 and Rx #1) may be used as the spacing D_(T2H) from thehorizontal position of the leftmost antenna Tx #1 of the first antennagroup.

Further, in FIG. 12A, the vertical position of the fourth antenna (Tx#4) is a position that is at a spacing D_(RV) from the vertical positionof the third antenna group (Rx #1 to Rx #3), and the vertical positionof the second antenna (Tx #3) is a position that is at a spacing D_(TV)from the vertical position of the first antenna group (Tx #1 and Tx #2).Note here that, as mentioned above, the spacing D_(TV) and the spacingD_(RV) need only be set so that in a case where the first antenna group(Tx #1 and Tx #2) and the third antenna group (Rx #1, Rx #2, and Rx #3)are identical (if made to agree) in vertical position with each other,the vertical position (reference position) of the first and thirdantenna groups, the vertical position of the second antenna, and thevertical position of the fourth antenna are different positions (i.e. donot overlap).

FIG. 12B shows, as an example, an arrangement of a virtual receivingarray in which D_(H)=1.5D_(RH) and D_(TV)=2D_(RV) in FIG. 11A. It shouldbe noted that the relationship between D_(H) and D_(RH) or therelationship between D_(TV) and D_(RV) are not limited to these.

In the virtual receiving array shown in FIG. 12B, the HLA has anarrangement of six virtual antennas (VA #1, VA #4, VA #7, VA #2, VA #5,and VA #8 surrounded by dashed lines shown in FIG. 12B) in a straightline at irregular spacings (D_(H), D_(RH), and 2D_(RH)) in a horizontaldirection. Further, as in FIG. 8B, the VLA shown in FIG. 12B has anarrangement of three virtual antennas (VA #2, VA #10, and VA #6surrounded by dashed lines shown in FIG. 12B) arranged in a straightline at regular spacings (D_(RV)) in a vertical direction.

The HLA shown in FIG. 12B has an arrangement of virtual antennas linedup in a straight line at irregular spacings, so that the HLA has anenlarged aperture length. For example, the HLA has an enlarged aperturelength of 7.5D_(RH) in FIG. 12B, whereas the HLA has an aperture lengthof 5D_(RH) in FIG. 8B. This brings about a narrower horizontal main lobeand an effect of improving horizontal angular separation performance. Itshould be noted that enlarging a spacing (in FIG. 12A, 2D_(H)) in thethird antenna group brings about a trade-off between a narrower mainlobe and an increased side lobe level.

The foregoing has described Variations 1 to 3 of Embodiment 1.

It should be noted that even in a case where the transmitting antennaarrangement shown in any one of FIGS. 8A, 9A, 10A, 11A, and 12A is usedas a receiving antenna arrangement and the receiving antenna arrangementshown in any one of FIGS. 8A, 9A, 10A, 11A, and 12A is used as atransmitting antenna arrangement, it is possible to achieve aconfiguration which is similar to that of the arrangement of the virtualreceiving array shown in any one of FIGS. 8B, 9B, 10B, 11B, and 12B andbring about effects which are similar to those of the arrangement of thevirtual receiving array shown in any one of FIGS. 8B, 9B, 10B, 11B, and12B. The same applies to the after-mentioned other antenna arrangements.In this case, the number Nt of transmitting antennas is 3 or larger, andthe number Na of receiving antennas is 3 or larger.

Further, although Embodiment 1 has described a case where transmittingantennas and receiving antennas are arranged so as not to overlap in avertical direction, transmitting antennas and receiving antennas may bearranged so as not to overlap in a direction other than a verticaldirection (e.g. in horizontal direction). For example, in FIGS. 8A, 10A,11A, and 12A, the arrangement of the transmitting array antenna and thereceiving array antenna may be rotated 90 degrees or −90 degrees. Inthis case, the arrangement of the antennas that constitute thetransmitting array antenna and the receiving array antenna is anarrangement in which the antennas do not overlap in a horizontaldirection. As a result, the horizontal size of the antennas thatconstitute the transmitting array antenna and the receiving arrayantenna can be an arbitrary size. Further, in this case, with thelimited number Nt of transmitting antennas being 3 and the limitednumber Na of receiving antennas being 3, the virtual receiving arrayallows as many virtual antennas as (Number of Transmitting Antennas ofSecond Antenna+Number of Receiving Antennas of Fourth Antenna+1) to belined up in a vertical direction and allows as many virtual antennas asthe product of the number of transmitting antennas of the first antennagroup and the number of receiving antennas of the third antenna group tobe lined up in a straight line in a horizontal direction, thus making itpossible to maximally enlarge the aperture lengths of the virtualreceiving array.

Embodiment 2

A rider apparatus according to Embodiment 2 is described with continuedreference to FIG. 4, as it shares a common basic configuration with theradar apparatus 10 according to Embodiment 1.

Embodiment 1 has described a case where a transmitting array antenna isconstituted by a first antenna group and a second antenna composed of asingle transmitting antenna 106. On the other hand, Embodiment 2describes a case where a transmitting array antenna is constituted by afirst antenna group and a “second antenna group” including a pluralityof transmitting antennas 106.

That is, in Embodiment 2, the Nt transmitting antennas 106 (transmittingarray antenna) include a “first antenna group” including a plurality oftransmitting antennas 106 that are identical in vertical position anddifferent in horizontal position and a “second antenna” including aplurality of transmitting antennas 106 placed in positions differentfrom the vertical and horizontal positions of the transmitting antennas106 of the first antenna group.

Further, in Embodiment 2, the Na receiving antennas 202 (receiving arrayantenna) include a “third antenna group” including a plurality ofreceiving antennas 202 that are identical in vertical position anddifferent in horizontal position and a “fourth antenna” that is areceiving antenna 202 placed in a position different from the verticaland horizontal positions of the receiving antennas 202 of the thirdantenna group.

The following describes example arrangements of transmitting andreceiving antennas according to Embodiment 2.

FIG. 13A shows an example arrangement of transmitting antennas 106 andreceiving antennas 202. Further, FIG. 13B shows an arrangement of avirtual receiving array that is obtained by the antenna arrangementshown in FIG. 13A.

(1) Arrangement of Transmitting and Receiving Antennas

FIG. 13A assumes that the number Nt of transmitting antennas 106 is 4and the number Na of receiving antennas 202 is 4. Further, the threetransmitting antennas 106 are denoted by Tx #1 to Tx #4, and the fourreceiving antennas 202 are denoted by Rx #1 to Rx #4.

In FIG. 13A, the receiving antennas Rx #1 to Rx #3 constitute a thirdantenna group of receiving antennas that are identical in verticalposition and different in horizontal position. Specifically, in FIG.13A, the horizontal interelement spacings D_(RH) between the receivingantennas Rx #1 to Rx #3 of the third antenna group are constant (regularspacings).

Further, in FIG. 13A, the receiving antenna Rx #4 is a fourth antennaplaced in a position different from both the horizontal and verticalpositions in which the third antenna group is placed. Specifically, inFIG. 13A, the horizontal position of the receiving antenna Rx #4, whichis the fourth antenna, is a position that is at a spacing D_(RH) outward(rightward) in a horizontal direction from the horizontal position of areceiving antenna at one end of the third antenna group (the leftmostantenna Rx #1 or the rightmost antenna Rx #3. In the example shown inFIG. 13A, the rightmost antenna Rx #3).

Further, in FIG. 13A, the vertical position of the fourth antenna (Rx#4) is a position that is at a spacing D_(RV) from the vertical positionof the third antenna group (Rx #1 to Rx #3).

Meanwhile, in FIG. 13A, the transmitting antennas Tx #1 and Tx #2constitute a first antenna group of transmitting antennas that areidentical in vertical position and different in horizontal position.Further, in FIG. 13A, the transmitting antennas Tx #3 and Tx #4constitute a second antenna group placed in a position different fromboth the horizontal and vertical positions in which the first antennagroup is placed.

Specifically, in FIG. 13A, the horizontal interelement spacing D_(TH)between the transmitting antennas Tx #1 and Tx #2 of the first antennagroup is a spacing (D_(Z)+D_(RH)) obtained by adding the spacing D_(RH)to the horizontal antenna aperture length D_(Z) of the third antennagroup (Rx #1, Rx #2, and Rx #3). For example, in the interelementspacing D_(TH) of the first antenna group, the spacing D_(RH) that isadded to the antenna aperture length D_(Z) is equal to theaforementioned horizontal spacing (in FIG. 13A, D_(RH)) between thethird antenna group and the fourth antenna.

Further, in FIG. 13A, the horizontal positions of the transmittingantennas Tx #3 and Tx #4 of the second antenna group are positionsdisplaced by spacings D_(T2H1) and D_(T2H2), respectively, inward in ahorizontal direction within the range of horizontal aperture of thefirst antenna group (in FIG. 13A, within the range inside the horizontalpositions of the end-point antennas Tx #1 and Tx #2) from the horizontalposition of either antenna of the first antenna group (Tx #1 and Tx #2).

For example, as shown in FIG. 13A, in a case where the horizontalposition of the fourth antenna (Rx #4) is on the outer side (right side)of the horizontal position of the rightmost antenna Rx #3 of the thirdantenna group, the interelement spacing between antennas in the thirdantenna group based on the leftmost antenna Rx #1 of the third antennagroup (in the case of FIG. 13A, the spacing D_(RH) between Rx #1 and Rx#2 or the spacing 2D_(RH) between Rx #1 and Rx #3) may be used as thespacing D_(T2H1) or D_(T2H2) from the horizontal position of therightmost antenna Tx #2 of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #4) is on the outer side (left side) of thehorizontal position of the leftmost antenna Rx #1 of the third antennagroup, the interelement spacing between antennas in the third antennagroup based on the rightmost antenna Rx #3 of the third antenna group(for example, in the case of the third antenna group shown in FIG. 13A,the spacing D_(RH) between Rx #3 and Rx #2 or the spacing 2D_(RH)between Rx #3 and Rx #1) may be used as the spacing D_(T2H1) or D_(T2H2)from the horizontal position of the leftmost antenna Tx #1 of the firstantenna group.

That is, the horizontal interelement spacing (in FIG. 13A, D_(RH) or2D_(RH)) between a receiving antenna (in FIG. 13A, Rx #1) of the thirdantenna group (in FIG. 13A, Rx #1 to Rx #3) located at an end on a sideopposite (second side; in FIG. 13A, the left side) to a side (firstside; in FIG. 13A, the right side) close to the position in which thefourth antenna (Rx #4) is placed and each of the other antennas (in FIG.13A, Rx #2 and Rx #3) of the third antenna group is identical to thehorizontal interelement spacing (in FIG. 13A, 2D_(RH) or D_(RH)) betweenthe transmitting antenna Tx #2, of the adjacent transmitting antennas Tx#1 and Tx #2 of the first antenna group, that is located on the sameside (in FIG. 13A, the right side) as the first side and each of thetransmitting antennas (Tx #3 and Tx #4) of the second antenna group.

In other words, the horizontal interelement spacing (in FIG. 13A,D_(T2H1)=2D_(RH) or D_(T2H2)=D_(RH)) between a transmitting antenna (inFIG. 13A, the rightmost antenna Tx #2), of the transmitting antennas (inFIG. 13A, Tx #1 and Tx #2) of the first antenna group, that is locatedon a first side (in FIG. 13A, the right side) and each of thetransmitting antennas (Tx #3 and Tx #4) of the second antenna group isidentical to the interelement spacing (in FIG. 13A, D_(RH) or 2D_(RH))between a receiving antenna (in FIG. 13A, the leftmost antenna Rx #1) ofthe receiving array antenna located at an end on a side opposite (inFIG. 13A, the left side) to the first side of the first antenna groupand each of the other receiving antennas (in FIG. 13A, Rx #2 and Rx #3).

Further, in FIG. 13A, the vertical positions of the transmittingantennas Tx #3 and Tx #4 of the second antenna group are positions thatare at spacings D_(TV1) and D_(TV2), respectively, from the verticalposition of the first antenna group (Tx #1 and Tx #2).

Note here that the spacings D_(TV1) and D_(TV2) are spacings that aredifferent from the vertical spacing D_(RV) between the third antennagroup and the fourth antenna. In other words, the spacings D_(TV1) andD_(TV2) and the spacing D_(RV) need only be set so that in a case wherethe first antenna group (Tx #1 and Tx #2) and the third antenna group(Rx #1, Rx #2, and Rx #3) are identical (if made to agree) in verticalposition with each other, the vertical position (reference position) ofthe first and third antenna groups, the vertical position of each of thetransmitting antennas (Tx #3 and Tx #4) of the second antenna group, andthe vertical position of the fourth antenna are different positions(i.e. do not overlap).

As shown in FIG. 13A, the arrangement of the transmitting antennas Tx #1to Tx #4 that constitute the transmitting array antenna is anarrangement in which the antennas do not overlap in a verticaldirection. For this reason, the vertical size of the transmittingantennas Tx #1 to Tx #4 that constitute the transmitting array antennacan be an arbitrary size. Similarly, as shown in FIG. 13A, thearrangement of the receiving antennas Rx #1 to Rx #4 that constitute thereceiving array antenna is an arrangement in which the antennas do notoverlap in a vertical direction. For this reason, the vertical size ofthe receiving antennas Rx #1 to Rx #4 that constitute the receivingarray antenna can be an arbitrary size.

(2) Arrangement of Virtual Receiving Array

The arrangement of the virtual receiving array (virtual antennas VA #1to VA #16) shown in FIG. 13B, which is constituted by the antennaarrangement shown in FIG. 13A described above, has the followingcharacteristics.

The virtual receiving array shown in FIG. 13B is configured to include ahorizontal virtual linear array antenna HLA composed of six virtualantennas (VA #1, VA #5, VA #9, VA #2, VA #6, and VA #10 surrounded bydashed lines shown in FIG. 13B) arranged in a straight line atinterelement spacings D_(RH) (regular spacings) in a horizontaldirection. The HLA shown in FIG. 13B is obtained from a horizontalpositional relationship between the two transmitting antennas Tx #1 andTX #2 of the first antenna group placed at an interelement spacingD_(TH) in a horizontal direction in FIG. 13A and the three receivingantennas Rx #1, Rx #2, and Rx #3 of the third antenna group placed atinterelement spacings D_(RH) in a horizontal direction in FIG. 13A.Specifically, the number of virtual antennas that are lined up in astraight line in a horizontal direction has such a relationship as to bethe product (in FIG. 13B, 6) of the number of antennas (in FIG. 13A, 2)of the first antenna group and the number of antennas (in FIG. 13A, 3)of the third antenna group.

Further, in FIG. 13A, the interelement spacings D_(RH) between theplurality of receiving antennas (Rx #1 to Rx #3) of the third antennagroup are equal. Further, the interelement spacings (D_(RH)) between theplurality of receiving antennas of the third antenna group and thespacing (D_(RH)) between the third antenna group and the fourth antenna(Rx #4) in a horizontal direction are equal. This causes the six virtualantennas to be placed at regular spacings in a straight line in ahorizontal direction in the HLA of the virtual receiving array shown inFIG. 13B.

Further, the virtual receiving array shown in FIG. 13B is configured toinclude a vertical virtual linear array antenna VLA composed of fourvirtual antennas (VA #2, VA #13, VA #8, and VA #11 surrounded by dashedlines shown in FIG. 13B) arranged in a straight line in a verticaldirection. The number of virtual antennas that are lined up in astraight line in a vertical direction has such a relationship as to be“(Number of Antennas of Second Antenna Group)+(Number of Antennas ofFourth Antenna)+1” (in FIG. 13B, 4).

The VLA has an arrangement of virtual antennas lined up in ascendingorder of D_(TV1), D_(TV2), and D_(RV) from the vertical position of thefirst antenna group (Tx #1 and Tx #2). For example, in a case whereD_(TV1)>D_(TV2)>D_(RV), the interelement spacings between the virtualantennas within the VLA are D_(RV), (D_(TV2)−D_(RV)), and(D_(TV1)−D_(TV2)). Further, in a case where D_(TV2)>D_(TV1)>D_(RV), theinterelement spacings between the virtual antennas within the VLA areD_(RV), (D_(TV1)−D_(RV)), and (D_(TV2)−D_(TV1))

Note here that when D_(TV1)=2D_(RV) and D_(TV2=3)D_(RV) or whenD_(TV1)=3D_(RV) and D_(TV2=2)D_(RV), the VLA has an arrangement ofvirtual antennas lined up in a straight line in a vertical direction atregular spacings (D_(RV)). Further, when D_(RV)=2D_(TV1) andD_(TV2=3)D_(TV1), the VLA has an arrangement of virtual antennas linedup in a straight line in a vertical direction at regular spacings(D_(TV1)). Further, when D_(RV)=2D_(TV2) and D_(TV1)=3D_(TV2), the VLAhas an arrangement of virtual antennas lined up in a straight line in avertical direction at regular spacings (D_(TV2)).

FIG. 13B shows, as an example, an example where D_(TV1)=3D_(RV) andD_(TV)1=2D_(RV) (i.e. a case where D_(TV)1>D_(TV2)>D_(RV)). That is, inFIG. 13B, the VLA has an arrangement of VA #2, VA #13, VA #8, and VA #11lined up in a straight line in a vertical direction at regular spacings(D_(RV)). This makes it possible to reduce a peak side lobe ratio in avertical direction.

That is, in a case where it is assumed that the first antenna group andthe third antenna group are identical in position in a verticaldirection, the spacings between the first antenna group (Tx #1 and TX#2) (or the third antenna group (Rx #1 to Rx #3)), each of thetransmitting antennas (Tx #3 and Tx #4) of the second antenna group, andthe fourth antenna (Rx #4) may be equal spacings or unequal spacings.

For example, in a case where D_(TV)1>D_(TV2)>D_(RV), placing the virtualantennas at interelement spacings D_(RV), (D_(TV2)−D_(RV))>D_(RV), and(D_(TV1)−D_(TV2))>D_(RV) within the VLA causes the VLA to be anunequally-spaced array. Causing the VLA to be an unequally-spaced arrayallows the VLA to have an enlarged aperture length. This brings about anarrower main lobe and an effect of improving vertical angularseparation performance.

Note here that, as shown in Eq. (4), Eq. (7), and FIG. 13B, with theposition (vertical position, horizontal position) of VA #1 as thereference position (0, 0), the virtual antenna VA #2 of the VLA isobtained from a relationship between the receiving antenna Rx #1 and thetransmitting antenna Tx #2, the virtual antenna VA #8 of the VLA isobtained from a relationship between the receiving antenna Rx #2 and thetransmitting antenna Tx #4, the virtual antenna VA #11 of the VLA isobtained from a relationship between the receiving antenna Rx #3 and thetransmitting antenna Tx #3, and the virtual antenna VA #13 of the VLA isobtained from a relationship between the receiving antenna Rx #4 and thetransmitting antenna Tx #1.

At this point in time, as described in Embodiment 1, by making theinterelement spacing D_(TH) of the first antenna group equal to the sumof the aperture length D_(Z) of the third antenna group and the spacingD_(RH) between the third antenna group and the fourth antenna in ahorizontal direction, i.e. the horizontal aperture length of thereceiving array antenna, the virtual antennas VA #2 and VA #13 of theVLA are placed in an identical horizontal position and lined up side byside in a vertical direction.

Further, the interelement spacing D_(T2H1) between the right end (inFIG. 13A, the rightmost antenna Tx #2) of the first antenna group andthe transmitting antenna Tx #3 of the second antenna group in ahorizontal direction is equal to the interelement spacing 2D_(RH) fromthe leftmost antenna Rx #1 of the third antenna group to anotherreceiving antenna Rx #3 of the third antenna group. As a result, thehorizontal position of the virtual antenna VA #2 obtained from therelationship between Rx #1 and Tx #2 and the horizontal position of thevirtual antenna VA #11 obtained from the relationship between Rx #2 andTx #3 become identical (in FIG. 13B, a position that is at a spacing3D_(RH) from the reference position). Similarly, the interelementspacing D_(T2H2) between the right end (in FIG. 13A, the rightmostantenna Tx #2) of the first antenna group and the transmitting antennaTx #4 of the second antenna group in a horizontal direction is equal tothe interelement spacing D_(RH) from the leftmost antenna Rx #1 of thethird antenna group to another receiving antenna Rx #2 of the thirdantenna group. As a result, the horizontal position of the virtualantenna VA #2 obtained from the relationship between Rx #1 and Tx #2 andthe horizontal position of the virtual antenna VA #8 obtained from therelationship between Rx #2 and Tx #4 become identical (in FIG. 13B, aposition that is at a spacing 3D_(RH) from the reference position).

Further, when the vertical position of the first and third antennagroups is a reference position, the vertical positions of thetransmitting antennas Tx #3 and Tx #4 and the receiving antenna Rx #4are different by D_(TV1), D_(TV2), and D_(RV), respectively. Therefore,in the vertical receiving array, too, the vertical positions of VA #11,VA #8, and VA #13 are different by D_(TV1), D_(TV2), and D_(RV),respectively, from the vertical position of VA #2.

Thus, VA #2, VA #13, VA #8, and VA #11, which constitute the VLA, areplaced in an identical horizontal position and different verticalpositions.

In this way, with the limited number Nt of transmitting antennas being 4and the limited number Na of receiving antennas being 4, the arrangementof antennas that constitute a transmitting array antenna and a receivingarray antenna shown in FIG. 13A allows the arrangement of the virtualreceiving array (VA #1, . . . , VA #16) shown in FIG. 13B to be anarrangement of six antennas (HLA) in a straight line in a horizontaldirection and four antennas (VLA) in a straight line in a verticaldirection, thus making it possible to maximally enlarge the aperturelengths of the virtual receiving array.

The direction estimator 214 performs horizontal and verticaldirection-of-arrival estimation processes in a manner similar toEmbodiment 1 with use of signals received by a virtual receiving array(see FIG. 13B) obtained from the aforementioned arrangement oftransmitting and receiving antennas (see FIG. 13A).

As noted above, using the array arrangement shown in FIG. 13A preventsantennas from overlapping in a vertical direction in the radar apparatus10 (MIMO radar), thus making it possible to use sub-array antennas of anarbitrary size in a vertical direction. Further, using the arrayarrangement shown in FIG. 13A makes it possible to maximize an apertureplane constituted by the horizontal and vertical directions of thevirtual receiving array shown in FIG. 13B.

Further, by including the plurality of transmitting antennas 106 in thesecond antenna group of the transmitting array antenna, Embodiment 2 canincrease the number of virtual antennas within the VLA, i.e. thevertical aperture length, of the virtual receiving array in comparisonwith Embodiment 1.

Therefore, according to Embodiment 1, the radar apparatus 10 canmaximally enlarge the vertical and horizontal aperture lengths of avirtual receiving array in performing two-dimensional vertical andhorizontal beam scanning with use of a MIMO radar, thus allowinghigh-resolution angle measuring in vertical and horizontal directions.That is, Embodiment 1 makes it possible to maximally enlarge thevertical and horizontal aperture lengths of a virtual receiving arraywithout deterioration in detection performance of a radar apparatus andimprove angular resolution with a small number of antenna elements.

In FIG. 13A, the spacings between the transmitting antennas Tx #1 to Tx#4 and the receiving antennas Rx #1 to Rx #4 do not affect thearrangement of the virtual receiving array. Note, however, that sincethe proximity of the transmitting antennas Tx #1 to Tx #4 and thereceiving antennas Rx #1 to Rx #4 enhances the degree of couplingbetween the transmitting and receiving antennas, it is preferable thatthey be arranged as far from one another as possible within theallowable antenna size. The same applies to the after-mentioned otherantenna arrangements.

Further, although FIG. 13A (including the arrangements shown in FIGS.14A, 15, 16, 17A, and 18A described below) has been described by taking,as an example, a case where the number Nt of transmitting antennas is 4and the number Na of receiving antennas is 4, the number Nt oftransmitting antennas and the number Na of receiving antennas are notlimited to 4. For example, as long as the first antenna group includesat least two transmitting antennas and the third antenna group includesat least three receiving antennas, it is possible to bring about effectswhich are similar to those of Embodiment 2. Further, the first antennagroup needs only include at least two transmitting antennas. That is,the minimum antenna configuration in Embodiment 2 is such that thenumber Nt of transmitting antennas is 4 and the number Na of receivingantennas is 4. Similarly, as for the after-mentioned other antennaarrangements, too, the minimum antenna configuration is such that thenumber Nt of transmitting antennas is 4 and the number Na of receivingantennas is 4.

For example, the number of virtual antennas that constitute the HLA inthe virtual receiving array corresponds to the product of the number oftransmitting antennas of the first antenna group and the number ofreceiving antennas of the third antenna group. Therefore, the larger thenumber of transmitting antennas of the first antenna group or the numberof receiving antennas of the third antenna group becomes, the larger thenumber of virtual antennas that constitute the HLA becomes. This bringsabout a narrower horizontal main lobe and an effect of improvinghorizontal angular separation performance.

Similarly, the larger the number of transmitting antennas of the secondantenna group becomes, the larger the number of virtual antennas thatconstitute the VLA becomes. This brings about a narrower vertical mainlobe and an effect of improving vertical angular separation performance.

Variation 1 of Embodiment 2

FIG. 13A has shown a case where there is agreement between the direction(downward) in which the vertical position of the second antenna group isplaced with respect to the vertical position of the first antenna groupand the direction (downward) in which the vertical position of thefourth antenna is placed with respect to the vertical position of thethird antenna group. However, there does not need to be agreementbetween the direction in which the vertical position of the secondantenna group is placed with respect to the vertical position of thefirst antenna group and the direction in which the vertical position ofthe fourth antenna is placed with respect to the vertical position ofthe third antenna group. The same applies to the after-mentioned otherantenna arrangements.

FIG. 14A shows an example arrangement of transmitting antennas 106 andreceiving antennas 202 according to Variation 1 of Embodiment 2.Further, FIG. 14B shows an arrangement of a virtual receiving array thatis obtained by the antenna arrangement shown in FIG. 14A.

As with FIG. 13A, FIG. 14A assumes that the number Nt of transmittingantennas 106 is 4 and the number Na of receiving antennas 202 is 4.Further, the four transmitting antennas 106 are denoted by Tx #1 to Tx#4, and the four receiving antennas 202 are denoted by Rx #1 to Rx #4.

Further, in FIG. 14A, as in FIG. 13A, the horizontal interelementspacings D_(RH) between the receiving antennas Rx #1 to Rx #3 of thethird antenna group are constant (regular spacings), and the horizontalposition of the receiving antenna Rx #4, which is the fourth antenna, isa position that is at a spacing D_(RH) outward (rightward) in ahorizontal direction from the horizontal position of a receiving antennaat one end of the third antenna group (the leftmost antenna Rx #1 or therightmost antenna Rx #3. In the example shown in FIG. 14A, the rightmostantenna Rx #3).

Further, in FIG. 14A, as in FIG. 13A, the horizontal interelementspacing D_(TH) between the transmitting antennas Tx #1 and Tx #2 of thefirst antenna group is a spacing (D_(Z)+D_(RH)) obtained by adding thespacing D_(RH) to the horizontal antenna aperture length D_(Z) of thethird antenna group (Rx #1, Rx #2, and Rx #3), and the horizontalpositions of the transmitting antenna Tx #3 and Tx #4 of the secondantenna group are positions that are at spacings D_(T2H1) (=2D_(RH)) andD_(T2H2) (=D_(RH)), respectively, inward in a horizontal direction fromthe horizontal position of a transmitting antenna at one end of thefirst antenna group (Tx #1 or Tx #2. In the example shown in FIG. 14A,Tx #2).

Further, in FIG. 14A, the vertical positions of the second antenna group(Tx #3 and Tx #4) are positions that are at spacings D_(TV1) andD_(TV2), respectively, downward from the vertical position of the firstantenna group (Tx #1 and Tx #2). Meanwhile, in FIG. 14A, the verticalposition of the fourth antenna (Rx #4) is a position that is at aspacing D_(RV) upward from the vertical position of the third antennagroup (Rx #1, Rx #2, and Rx #3). That is, the direction in which thevertical positions of the second antenna group are placed with respectto the vertical position of the first antenna group and the direction inwhich the vertical position of the fourth antenna is placed with respectto the vertical position of the third antenna group are different.

For example, in FIG. 14A, D_(TV1)=2D_(RV) and D_(TV2)=D_(RV). Assumehere that, in FIG. 14A, an upward direction and a downward directionfrom the vertical position of the first antenna group (Tx #1 and Tx #2)are a “positive direction” and a negative direction”, respectively.Similarly, assume that, in FIG. 14A, an upward direction and a downwarddirection from the vertical position of the third antenna group (Rx #1to Rx #3) are a “positive direction” and a negative direction”,respectively. In this case, in FIG. 14A, the second antenna group (Tx #3and Tx #4) are placed in positions that are at spacings D_(TV1) andD_(TV2), respectively, in the negative direction from the first antennagroup, and the fourth antenna (Rx #4) is placed in a position that is ata spacing D_(RV) in the positive direction from the third antenna group.That is, even if D_(TV2)=D_(RV), the spacing D_(TV2) and the spacingD_(RV) are deemed as different spacings, as the positive direction andthe negative direction are different.

Further, without being limited to D_(TV1)=2D_(RV) or D_(TV2)=D_(RV), thespacings D_(TV1) and D_(TV2) and the spacing D_(RV) need only be set sothat in a case where the first antenna group (Tx #1 and Tx #2) and thethird antenna group (Rx #1, Rx #2, and Rx #3) are identical (if made toagree) in vertical position with each other, the vertical position(reference position) of the first and third antenna groups, the verticalposition of each of the transmitting antennas of the second antennagroup, and the vertical position of the fourth antenna are differentpositions (i.e. do not overlap).

In this case, too, as in FIG. 13B, the virtual receiving array shown inFIG. 14B is configured to include an HLA composed of six virtualantennas (VA #1, VA #5, VA #9, VA #2, VA #6, and VA #10 (VA #16)surrounded by dashed lines shown in FIG. 14B) arranged in a straightline at interelement spacings D_(RH) (regular spacings) in a horizontaldirection.

Further, as in FIG. 13B, the virtual receiving array shown in FIG. 14Bis configured to include a VLA composed of four virtual antennas (VA#13, VA #2, VA #8, and VA #11 surrounded by dashed lines shown in FIG.14B) arranged in a straight line in a vertical direction.

As shown in FIGS. 14A and 14B, in a case where the vertical position ofthe second antenna group is placed at spacings downward from thevertical position of the first antenna group, the VLA includes virtualantennas placed in positions that are at spacings D_(TV1) (=2D_(RV)) andD_(TV2) (=D_(RV)), respectively, downward from the vertical position ofthe first antenna group. Further, as shown in FIGS. 14A and 14B, in acase where the vertical position of the fourth antenna is placed at aspacing upward from the vertical position of the third antenna group,the VLA includes virtual antennas placed in positions that are at aspacing D_(RV) upward from the vertical position of the first antennagroup.

Note here that when D_(TV1)=2D_(RV) and D_(TV2)=D_(RV), the VLA shown inFIG. 14B has an arrangement of virtual antennas lined up in a straightline in a vertical direction at regular spacings (D_(RV)).

It should be noted that, in a vertical direction, the vertical positionin which each transmitting antenna 106 of the second antenna group isplaced with respect to the vertical position of the first antenna groupand the vertical position in which the fourth antenna is placed withrespect to the vertical position of the third antenna group are notlimited to the example shown in FIG. 14A.

For example, in an antenna arrangement shown in FIG. 15, the verticalposition of Tx #3 of the second antenna group (Tx #3 and Tx #4) isplaced at a spacing D_(TV1) downward (in the negative direction) fromthe vertical position of the first antenna group (Tx #1 and Tx #2), andthe vertical position of Tx #4 of the second antenna group (Tx #3 and Tx#4) is placed at a spacing D_(TV2) upward (in the positive direction)from the vertical position of the first antenna group (Tx #1 and Tx #2).Further, in FIG. 15, the vertical position of the fourth antenna (Rx #4)is placed at a spacing D_(RV) downward (in the negative direction) fromthe vertical position of the third antenna group (Rx #1, Rx #2, and Rx#3). In this case, the VLA (not illustrated) of a virtual receivingarray that is obtained from the antenna arrangement of FIG. 15 includesvirtual antennas placed in positions that are at a spacing D_(TV1)downward and a spacing D_(TV2) upward, respectively, from the verticalposition of the first antenna group and a virtual antenna placed in aposition that is at a spacing D_(RV) downward from the vertical positionof the first antenna group. Further, for example, when D_(TV1)=2D_(RV)and D_(TV2)=D_(RV), the VLA of a virtual receiving array that isobtained from the antenna arrangement of FIG. 15 has an arrangement ofvirtual antennas lined up in a straight line in a vertical direction atregular spacings (D_(RV)) (not illustrated).

Alternatively, for example, in an antenna arrangement shown in FIG. 16,the vertical positions of the second antenna group (Tx #3 and Tx #4) maybe placed at spacings D_(TV1) and D_(TV2), respectively, upward (in thepositive direction) from the vertical position of the first antennagroup, and the vertical position of the fourth antenna (Rx #4) may beplaced at a spacing D_(RV) downward (in the negative direction) from thevertical position of the third antenna group (Rx #1, Rx #2, and Rx #3).In this case, the VLA (not illustrated) of a virtual receiving arraythat is obtained from the antenna arrangement of FIG. 16 includesvirtual antennas placed in positions that are at spacings D_(TV1) andD_(TV2), respectively upward from the vertical position of the firstantenna group and a virtual antenna placed in a position that is at aspacing D_(RV) downward from the vertical position of the first antennagroup. Further, for example, when D_(TV1)=2D_(RV) and D_(TV2)=D_(RV),the VLA of a virtual receiving array that is obtained from the antennaarrangement of FIG. 16 has an arrangement of virtual antennas lined upin a straight line in a vertical direction at regular spacings (D_(RV))(not illustrated).

Even such an antenna arrangement according to Variation 1 of Embodiment2 can bring about effects which are similar to those of Embodiment 2.

Variation 2 of Embodiment 2

FIG. 13B has described a configuration including an HLA composed of sixvirtual antennas (VA #1, VA #5, VA #9, VA #2, VA #6, and VA #10)arranged in a straight line at interelement regular spacings (D_(RH)) ina horizontal direction. However, the HLA is not limited to a case ofbeing composed of virtual antennas placed at regular spacings but may becomposed of virtual antennas placed at irregular spacings.

FIG. 17A shows an example arrangement of transmitting antennas 106 andreceiving antennas 202 according to Variation 2 of Embodiment 1.Further, FIG. 17B shows an arrangement of a virtual receiving array thatis obtained by the antenna arrangement shown in FIG. 17A.

As with FIG. 13A, FIG. 17A assumes that the number Nt of transmittingantennas 106 is 4 and the number Na of receiving antennas 202 is 4.Further, the four transmitting antennas 106 are denoted by Tx #1 to Tx#4, and the four receiving antennas 202 are denoted by Rx #1 to Rx #4.

In FIG. 17A, as in FIG. 13A, the horizontal interelement spacings D_(RH)between the receiving antennas Rx #1 to Rx #3 of the third antenna groupare constant (regular spacings). Meanwhile, FIG. 17A assumes that thehorizontal position of the receiving antenna Rx #4, which is the fourthantenna, is a position that is at a spacing D_(H) outward (rightward) ina horizontal direction from the horizontal position of a receivingantenna at one end of the third antenna group (the leftmost antenna Rx#1 or the rightmost antenna Rx #3. In the example shown in FIG. 17A, therightmost antenna Rx #3). Note here that the interelement spacing D_(H)is a different value from the spacing D_(RH).

Further, in FIG. 17A, as in FIG. 13A, the horizontal position of thetransmitting antennas Tx #3 and Tx #4 of the second antenna group arepositions displaced by spacings D_(T2H1) and D_(T2H2), respectively,inward in a horizontal direction within the range of horizontal apertureof the first antenna group (in FIG. 11A, within the range inside thehorizontal positions of the end-point antennas Tx #1 and Tx #2) from thehorizontal position of either antenna of the first antenna group (Tx #1and Tx #2).

For example, as shown in FIG. 17A, in a case where the horizontalposition of the fourth antenna (Rx #4) is on the outer side (right side)of the horizontal position of the rightmost antenna Rx #3 of the thirdantenna group, the interelement spacing between antennas in the thirdantenna group based on the leftmost antenna Rx #1 of the third antennagroup (in the case of FIG. 17A, the spacing D_(RH) between Rx #1 and Rx#2 or the spacing 2D_(RH) between Rx #1 and Rx #3) may be used as thespacing D_(T2H1) or D_(T2H2) from the horizontal position of therightmost antenna Tx #2 of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #4) is on the outer side (left side) of thehorizontal position of the leftmost antenna Rx #1 of the third antennagroup, the interelement spacing between antennas in the third antennagroup based on the rightmost antenna Rx #3 of the third antenna group(for example, in the case of the third antenna group shown in FIG. 17A,the spacing D_(RH) between Rx #3 and Rx #2 or the spacing 2D_(RH)between Rx #3 and Rx #1) may be used as the spacing D_(T2H1) or D_(T2H2)from the horizontal position of the leftmost antenna Tx #1 of the firstantenna group.

Further, in FIG. 17A, the horizontal interelement spacing D_(TH) betweenthe transmitting antennas Tx #1 and Tx #2 of the first antenna group isa spacing (D_(Z)+D_(H)) obtained by adding the horizontal spacing(D_(H)) between the third antenna group and the fourth antenna to thehorizontal antenna aperture length D_(Z) of the third antenna group (Rx#1, Rx #2, and Rx #3).

Further, in FIG. 17A, the vertical position of the fourth antenna (Tx#4) is a position that is at a spacing D_(RV) from the vertical positionof the third antenna group (Rx #1 to Rx #3), and the vertical positionsof the transmitting antennas (Tx #3 and Tx #4) of the second antennagroup are positions that are at spacings D_(TV1) and D_(TV2),respectively, from the vertical position of the first antenna group (Tx#1 and Tx #2). Note here that, as mentioned above, the spacings D_(TV1)and D_(TV2) and the spacing D_(RV) need only be set so that in a casewhere the first antenna group (Tx #1 and Tx #2) and the third antennagroup (Rx #1, Rx #2, and Rx #3) are identical (if made to agree) invertical position with each other, the vertical position (referenceposition) of the first and third antenna groups, the vertical positionof each of the transmitting antennas (Tx #3 and Tx #4) of the secondantenna group, and the vertical position of the fourth antenna aredifferent positions (i.e. do not overlap).

FIG. 17B shows, as an example, an arrangement of a virtual receivingarray in which D_(H)=1.5D_(RH), D_(TV1)=3D_(RV), and D_(TV2=2)D_(RV) inFIG. 17A. It should be noted that the relationship between D_(H) andD_(RH) and the relationship between D_(TV1), D_(TV2), and D_(RV) are notlimited to these.

In the virtual receiving array shown in FIG. 17B, the HLA has anarrangement of six virtual antennas (VA #1, VA #5, VA #9, VA #2, VA #6,and VA #10 surrounded by dashed lines shown in FIG. 17B) in a straightline at irregular spacings (D_(H) and D_(RH)) in a horizontal direction.Further, as in FIG. 13B, the VLA shown in FIG. 17B has an arrangement offour virtual antennas (VA #2, VA #13, VA #8, and VA #11 surrounded bydashed lines shown in FIG. 17B) arranged in a straight line at regularspacings (D_(RV)) in a vertical direction.

Note here that in a case where D_(H)=D_(RH), the HLA has its virtualantennas lined up at regular spacings (D_(RH)) as in FIG. 13B. Thismakes it possible to reduce the peak side lobe ratio.

Meanwhile, when D_(H)>D_(RH), the HLA has an arrangement of virtualantennas lined up in a straight line at irregular spacings as shown inFIG. 17B, so that the HLA has an enlarged aperture length. For example,the HLA has an enlarged aperture length of 5.5D_(RH) in FIG. 17B,whereas the HLA has an aperture length of 5D_(RH) in FIG. 13B. Thisbrings about a narrower horizontal main lobe and an effect of improvinghorizontal angular separation performance. It should be noted thatenlarging the spacing D_(H) brings about a trade-off between a narrowermain lobe and an increased side lobe level.

Variation 3 of Embodiment 2

Although FIGS. 13A, 14A, 15, 16, and 17A have described cases where thehorizontal interelement spacings between the receiving antennas (Rx #1,Rx #2, and Rx #3) of the third antenna group are constant (D_(RH)), thehorizontal interelement spacings between the receiving antennas (Rx #1,Rx #2, and Rx #3) of the third antenna group may be irregular spacings.In this case, the HLA of the virtual receiving array is composed ofvirtual antennas placed at irregular spacings as in the case ofVariation 2 of Embodiment 2.

FIG. 18A shows an example arrangement of transmitting antennas 106 andreceiving antennas 202 according to Variation 3 of Embodiment 2.Further, FIG. 18B shows an arrangement of a virtual receiving array thatis obtained by the antenna arrangement shown in FIG. 18A.

As with FIG. 13A, FIG. 18A assumes that the number Nt of transmittingantennas 106 is 4 and the number Na of receiving antennas 202 is 4.Further, the four transmitting antennas 106 are denoted by Tx #1 to Tx#4, and the four receiving antennas 202 are denoted by Rx #1 to Rx #4.

FIG. 18A assumes that D_(RH) is the smallest value of the horizontalinterelement spacings between the receiving antennas Rx #1 to Rx #3 ofthe third antenna group. In FIG. 18A, D_(RH) is the interelement spacingbetween the receiving antennas Rx #1 and Rx #2, and 2D_(RH) is theinterelement spacing between the receiving antennas Rx #2 and Rx #3.That is, the interelement spacings between the receiving antennas Rx #1to Rx #3 of the third antenna group are different. It should be notedthat the interelement spacings in the third antenna group are notlimited to these.

Further, FIG. 18A assumes that the horizontal position of the receivingantenna Rx #4, which is the fourth antenna, is a position that is at aspacing D_(H) outward (rightward) in a horizontal direction from thehorizontal position of a receiving antenna at one end of the thirdantenna group (the leftmost antenna Rx #1 or the rightmost antenna Rx#3. In the example shown in FIG. 18A, the rightmost antenna Rx #3). Notehere that the interelement spacing D_(H) may be the same or a differentvalue as or from the spacings (D_(RH) and 2D_(RH)) between the receivingantennas (Rx #1 to Rx #3) of the third antenna group.

Further, in FIG. 18A, the horizontal interelement spacing D_(TH) betweenthe transmitting antennas Tx #1 and Tx #2 of the first antenna group isa spacing (D_(Z)+D_(H)) obtained by adding the horizontal spacing D_(H)(in FIG. 18A, D_(H)=D_(RH)) between the third antenna group and thefourth antenna to the horizontal antenna aperture length D_(Z) of thethird antenna group (Rx #1, Rx #2, and Rx #3).

Further, in FIG. 18A, as in FIG. 13A, the horizontal positions of thetransmitting antennas Tx #3 and Tx #4 of the second antenna group arepositions displaced by spacings D_(T2H1) and D_(T2H2), respectively,inward in a horizontal direction within the range of horizontal apertureof the first antenna group (in FIG. 18A, within the range inside thehorizontal positions of the end-point antennas Tx #1 and Tx #2) from thehorizontal position of either antenna of the first antenna group (Tx #1and Tx #2).

For example, as shown in FIG. 18A, in a case where the horizontalposition of the fourth antenna (Rx #4) is on the outer side (in FIG.18A, the right side) of the horizontal position of the rightmost antennaRx #3 of the third antenna group, the interelement spacing betweenantennas in the third antenna group based on the leftmost antenna Rx #1of the third antenna group (in the case of FIG. 18A, the spacing D_(RH)between Rx #1 and Rx #2 or the spacing 3D_(RH) between Rx #1 and Rx #3)may be used as the spacing D_(T2H1) or D_(T2H2) from the horizontalposition of the rightmost antenna Tx #2 of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #4) is on the outer side (in FIG. 18A, the leftside) of the horizontal position of the leftmost antenna Rx #1 of thethird antenna group, the interelement spacing between antennas in thethird antenna group based on the rightmost antenna Rx #3 of the thirdantenna group (for example, in the case of the third antenna group shownin FIG. 18A, the spacing 2D_(RH) between Rx #3 and Rx #2 or the spacing3D_(RH) between Rx #3 and Rx #1) may be used as the spacing D_(T2H1) orD_(T2H2) from the horizontal position of the leftmost antenna Tx #1 ofthe first antenna group.

Further, assume that, in FIG. 18A, an upward direction and a downwarddirection from the vertical position of the first antenna group (Tx #1and Tx #2) are a “positive direction” and a negative direction”,respectively. Similarly, assume that, in FIG. 18A, an upward directionand a downward direction from the vertical position of the third antennagroup (Rx #1 to Rx #3) are a “positive direction” and a negativedirection”, respectively. In this case, in FIG. 18A, the verticalposition of the fourth antenna (Rx #4) is a position that is at aspacing D_(RV) upward (in the positive direction) from the verticalposition of the third antenna group (Rx #1 to Rx #3), and the verticalpositions of the second antenna group (Tx #3 and Tx #4) are positionsthat are at spacings D_(TV1) and D_(TV2), respectively, downward (in thenegative direction) from the vertical position of the first antennagroup (Tx #1 and Tx #2). Note, however, that, as mentioned above, thespacings D_(TV1) and D_(TV2) and the spacing D_(RV) need only be set sothat in a case where the first antenna group (Tx #1 and Tx #2) and thethird antenna group (Rx #1, Rx #2, and Rx #3) are identical (if made toagree) in vertical position with each other, the vertical position(reference position) of the first and third antenna groups, the verticalposition of each of the transmitting antennas (Tx #3 and Tx #4) of thesecond antenna group, and the vertical position of the fourth antennaare different positions (i.e. do not overlap).

FIG. 18B shows, as an example, an arrangement of a virtual receivingarray in which D_(H)=1.5D_(RH), D_(TV1)=2D_(RV), and D_(TV2)=D_(RV) inFIG. 18A. It should be noted that the relationship between D_(H) andD_(RH) and the relationship between D_(TV1), D_(TV2), and D_(RV) are notlimited to these.

In the virtual receiving array shown in FIG. 18B, the HLA has anarrangement of six virtual antennas (VA #1, VA #5, VA #9, VA #2, VA #6,and VA #10 (VA #16) surrounded by dashed lines shown in FIG. 18B) in astraight line at irregular spacings (D_(H) and 2D_(RH)) in a horizontaldirection. Further, as in FIG. 13B, the VLA shown in FIG. 18B has anarrangement of four virtual antennas (VA #13, VA #2, VA #8, and VA #11surrounded by dashed lines shown in FIG. 18B) arranged in a straightline at regular spacings (D_(RV)) in a vertical direction.

The HLA shown in FIG. 18B has an arrangement of virtual antennas linedup in a straight line at irregular spacings, so that the HLA has anenlarged aperture length. For example, the HLA has an enlarged aperturelength of 7D_(RH) in FIG. 18B, whereas the HLA has an aperture length of5D_(RH) in FIG. 13B.

This brings about a narrower horizontal main lobe and an effect ofimproving horizontal angular separation performance. It should be notedthat enlarging a spacing (in FIG. 18A, 2D_(H)) in the third antennagroup brings about a trade-off between a narrower main lobe and anincreased side lobe level.

The foregoing has described Variations 1 to 3 of Embodiment 2.

It should be noted that even in a case where the transmitting antennaarrangement shown in any one of FIGS. 13A, 14A, 15, 16, 17A, and 18A isused as a receiving antenna arrangement and the receiving antennaarrangement shown in any one of FIGS. 13A, 14A, 15, 16, 17A, and 18A isused as a transmitting antenna arrangement, it is possible to achieve aconfiguration which is similar to that of the arrangement of the virtualreceiving array shown in any one of FIGS. 13B, 14B, 17B, and 18B (Note,however, that a virtual receiving array corresponding to FIG. 15 or 16is not illustrated.) and bring about effects which are similar to thoseof the arrangement of the virtual receiving array shown in any one ofFIGS. 13B, 14B, 17B, and 18B. The same applies to the after-mentionedother antenna arrangements. In this case, the number Nt of transmittingantennas is 4 or larger, and the number Na of receiving antennas is 4 orlarger.

Further, although Embodiment 1 has described a case where transmittingantennas and receiving antennas are arranged so as not to overlap in avertical direction, transmitting antennas and receiving antennas may bearranged so as not to overlap in a direction other than a verticaldirection (e.g. in horizontal direction). For example, in FIGS. 13A,14A, 15, 16, 17A, and 18A, the arrangement of the transmitting arrayantenna and the receiving array antenna may be rotated 90 degrees or −90degrees. In this case, the arrangement of the antennas that constitutethe transmitting array antenna and the receiving array antenna is anarrangement in which the antennas do not overlap in a horizontaldirection. As a result, the horizontal size of the antennas thatconstitute the transmitting array antenna and the receiving arrayantenna can be an arbitrary size. Further, in this case, with thelimited number Nt of transmitting antennas being 4 and the limitednumber Na of receiving antennas being 4, the virtual receiving arrayallows as many virtual antennas as (Number of Transmitting Antennas ofSecond Antenna Group+Number of Receiving Antennas of Fourth Antenna+1)to be lined up in a vertical direction and allows as many virtualantennas as the product of the number of transmitting antennas of thefirst antenna group and the number of receiving antennas of the thirdantenna group to be lined up in a straight line in a horizontaldirection, thus making it possible to maximally enlarge the aperturelengths of the virtual receiving array.

The foregoing has described embodiments according to an aspect of thepresent disclosure.

It should be noted that a proper combination of actions according to theembodiments and variations may be carried out.

Other Embodiments

(1) The number Nt of transmitting antennas is not limited to threeelements or four elements, and the number Na of receiving antennas isnot limited to three elements or four elements. For example, in a casewhere the number of transmitting antennas of the second antenna group isn (which is an integer of not less than 1), the number of receivingantennas of the third antenna group needs only be at least (n+1).

As an example, a description is given of a case where the number Nt oftransmitting antennas is 5 and the number Na of receiving antennas is 5.

FIG. 19A shows an example antenna arrangement in which that the numberNt of transmitting antennas 106 is 5 and the number Na of receivingantennas 202 is 5. FIG. 19B shows an arrangement of a virtual receivingarray that is obtained by the antenna arrangement shown in FIG. 19A. Thefive transmitting antennas 106 are denoted by Tx #1 to Tx #5, and thefive receiving antennas 202 are denoted by Rx #1 to Rx #5.

In FIG. 19A, the receiving antennas Rx #1 to Rx #4 constitute a thirdantenna group of receiving antennas that are identical in verticalposition and different in horizontal position. Specifically, in FIG.19A, the horizontal interelement spacings D_(RH) between the receivingantennas Rx #1 to Rx #4 of the third antenna group are constant (regularspacings).

Further, in FIG. 19A, the receiving antenna Rx #5 is a fourth antennaplaced in a position different from both the horizontal and verticalpositions in which the third antenna group is placed. Specifically, inFIG. 19A, the horizontal position of the receiving antenna Rx #5, whichis the fourth antenna, is a position that is at a spacing D_(H) outward(rightward) in a horizontal direction from the horizontal position of areceiving antenna at one end of the third antenna group (the leftmostantenna Rx #1 or the rightmost antenna Rx #4. In the example shown inFIG. 19A, the rightmost antenna Rx #4). Note here that the interelementspacing D_(H) may be the same or a different value as or from thespacings (D_(RH)) between the receiving antennas (Rx #1 to Rx #4) of thethird antenna group.

Further, in FIG. 19A, the vertical position of the fourth antenna (Tx#5) is a position that is at a spacing D_(RV) from the vertical positionof the third antenna group (Rx #1 to Rx #4).

Meanwhile, in FIG. 19A, the transmitting antennas Tx #1 and Tx #2constitute a first antenna group of transmitting antennas that areidentical in vertical position and different in horizontal position.Further, in FIG. 19A, the transmitting antennas Tx #3, Tx #4, and Tx #5constitute a second antenna group placed in a position different fromboth the horizontal and vertical positions in which the first antennagroup is placed.

Specifically, in FIG. 19A, the horizontal interelement spacing D_(TH)between the transmitting antennas Tx #1 and Tx #2 of the first antennagroup is a spacing (D_(Z)+D_(H)) obtained by adding the spacing D_(H) tothe horizontal antenna aperture length D_(Z) of the third antenna group(Rx #1 to Rx #4). In FIG. 19A, in the interelement spacing D_(TH) of thefirst antenna group, the spacing D_(H) that is added to the antennaaperture length D_(Z) is equal to the aforementioned horizontal spacing(D_(RH)) between the third antenna group and the fourth antenna.

Further, in FIG. 19A, the horizontal positions of the transmittingantennas Tx #3, Tx #4, and Tx #5 of the second antenna group arepositions displaced by spacings D_(T2H1), D_(T2H2), and D_(T2H3),respectively, inward in a horizontal direction within the range ofhorizontal aperture of the first antenna group (in FIG. 19A, within therange inside the horizontal positions of the end-point antennas Tx #1and Tx #2) from the horizontal position of either antenna of the firstantenna group (Tx #1 and Tx #2).

For example, as shown in FIG. 19A, in a case where the horizontalposition of the fourth antenna (Rx #5) is on the outer side (in FIG.19A, the right side) of the horizontal position of the rightmost antennaRx #4 of the third antenna group, the interelement spacing betweenantennas in the third antenna group based on the leftmost antenna Rx #1of the third antenna group (in the case of FIG. 19A, the spacing D_(RH)between Rx #1 and Rx #2, the spacing 2D_(RH) between Rx #1 and Rx #3, orthe spacing 3D_(RH) between Rx #1 and Rx #4) may be used as the spacingD_(T2H1), D_(T2H2), or D_(T2H3) from the horizontal position of therightmost antenna Tx #2 of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #4) is on the outer side (in FIG. 19A, the leftside) of the horizontal position of the leftmost antenna Rx #1 of thethird antenna group, the interelement spacing between antennas in thethird antenna group based on the rightmost antenna Rx #4 of the thirdantenna group (for example, in the case of the third antenna group shownin FIG. 19A, the spacing D_(RH) between Rx #4 and Rx #3, the spacing2D_(RH) between Rx #4 and Rx #2, or the spacing 3D_(RH) between Rx #4and Rx #1) may be used as the spacing D_(T2H1), D_(T2H2), or D_(T2H3)from the horizontal position of the leftmost antenna Tx #1 of the firstantenna group.

Further, in FIG. 19A, the vertical positions of the transmittingantennas Tx #3, Tx #4, and Tx #5 of the second antenna group arepositions that are at spacings D_(TV1), D_(TV2), and D_(TV3),respectively, from the vertical position of the first antenna group (Tx#1 and Tx #2).

Note here that the spacings D_(TV1), D_(TV2), and D_(TV3) are spacingsthat are different from the vertical spacing D_(RV) between the thirdantenna group and the fourth antenna. In other words, the spacingsD_(TV1), D_(TV2), and D_(TV3) and the spacing D_(RV) need only be set sothat in a case where the first antenna group (Tx #1 and Tx #2) and thethird antenna group (Rx #1 to Rx #4) are identical (if made to agree) invertical position with each other, the vertical position (referenceposition) of the first and third antenna groups, the vertical positionof each of the transmitting antennas (Tx #3 to Tx #5) of the secondantenna group, and the vertical position of the fourth antenna aredifferent positions (i.e. do not overlap).

As shown in FIG. 19A, the arrangement of the transmitting antennas Tx #1to Tx #5 that constitute the transmitting array antenna is anarrangement in which the antennas do not overlap in a verticaldirection, as in the embodiments described above. For this reason, thevertical size of the transmitting antennas Tx #1 to Tx #5 thatconstitute the transmitting array antenna can be an arbitrary size.Similarly, as shown in FIG. 19A, the arrangement of the receivingantennas Rx #1 to Rx #5 that constitute the receiving array antenna isan arrangement in which the antennas do not overlap in a verticaldirection, as in the embodiments described above. For this reason, thevertical size of the receiving antennas Rx #1 to Rx #5 that constitutethe receiving array antenna can be an arbitrary size.

The arrangement of the virtual receiving array (virtual antennas VA #1to VA #25) shown in FIG. 19B, which is constituted by the antennaarrangement shown in FIG. 19A described above, has the followingcharacteristics.

The virtual receiving array shown in FIG. 19B is configured to include ahorizontal virtual linear array antenna HLA composed of eight virtualantennas (VA #1, VA #6, VA #11, VA #16, VA #2, VA #7 (VA #23), VA #12,and VA #17 surrounded by dashed lines shown in FIG. 19B) arranged in astraight line at interelement spacings D_(RH) (regular spacings) in ahorizontal direction. That is, the number of virtual antennas that arelined up in a straight line in a horizontal direction has such arelationship as to be the product (in FIG. 19A, 8) of the number ofantennas (in FIG. 19A, 2) of the first antenna group and the number ofantennas (in FIG. 19A, 4) of the third antenna group.

Further, the virtual receiving array shown in FIG. 19B is configured toinclude a vertical virtual linear array antenna VLA composed of fivevirtual antennas (VA #21, VA #10, VA #2, VA #14, and VA #18 surroundedby dashed lines shown in FIG. 19B) arranged in a straight line in avertical direction. The number of virtual antennas that are lined up ina straight line in a vertical direction has such a relationship as to be“(Number of Antennas of Second Antenna Group)+(Number of Antennas ofFourth Antenna)+1” (in FIG. 19B, 5).

In this way, with the limited number Nt of transmitting antennas being 5and the limited number Na of receiving antennas being 5, the arrangementof antennas that constitute a transmitting array antenna and a receivingarray antenna shown in FIG. 19A allows the arrangement of the virtualreceiving array (VA #1, . . . , VA #25) shown in FIG. 19B to be anarrangement of eight antennas (HLA) in a straight line in a horizontaldirection and five antennas (VLA) in a straight line in a verticaldirection, thus making it possible to maximally enlarge the aperturelengths of the virtual receiving array.

(2) Although the foregoing embodiments have described cases where thenumber of transmitting antennas of the first antenna group of thetransmitting array antenna is 2 (Tx #1 and Tx #2), the number oftransmitting antennas of the first antenna group may be 3 or larger.

As an example, a description is given of a case where the number Nt oftransmitting antennas is 5 and the number Na of receiving antennas is 4.

FIG. 20A shows an example antenna arrangement in which that the numberNt of transmitting antennas 106 is 5 and the number Na of receivingantennas 202 is 4. FIG. 20B shows an arrangement of a virtual receivingarray that is obtained by the antenna arrangement shown in FIG. 20A. Thefive transmitting antennas 106 are denoted by Tx #1 to Tx #5, and thefour receiving antennas 202 are denoted by Rx #1 to Rx #4.

In FIG. 20A, the receiving antennas Rx #1 to Rx #3 constitute a thirdantenna group of receiving antennas that are identical in verticalposition and different in horizontal position. Specifically, in FIG.20A, the horizontal interelement spacings D_(RH) between the receivingantennas Rx #1 to Rx #3 of the third antenna group are constant (regularspacings). It should be noted that the interelement spacings in thethird antenna group are not limited to these.

Further, in FIG. 20A, the receiving antenna Rx #4 is a fourth antennaplaced in a position different from both the horizontal and verticalpositions in which the third antenna group is placed. Specifically, inFIG. 20A, the horizontal position of the receiving antenna Rx #4, whichis the fourth antenna, is a position that is at a spacing D_(H) outward(rightward) in a horizontal direction from the horizontal position of areceiving antenna at one end of the third antenna group (the leftmostantenna Rx #1 or the rightmost antenna Rx #3. In the example shown inFIG. 20A, the rightmost antenna Rx #3). Note here that the interelementspacing D_(H) may be the same or a different value as or from thespacings (D_(RH)) between the receiving antennas (Rx #1 to Rx #3) of thethird antenna group. In FIG. 20A, D_(H)=D_(RH).

Further, in FIG. 20A, the vertical position of the fourth antenna (Tx#4) is a position that is at a spacing D_(RV) from the vertical positionof the third antenna group (Rx #1 to Rx #3).

Meanwhile, in FIG. 20A, the transmitting antennas Tx #1, Tx #2, and Tx#4 constitute a first antenna group of transmitting antennas that areidentical in vertical position and different in horizontal position.Further, in FIG. 20A, the transmitting antennas Tx #4 and Tx #5constitute a second antenna group placed in a position different fromboth the horizontal and vertical positions in which the first antennagroup is placed.

Specifically, in FIG. 20A, each of the horizontal interelement spacingsD_(TH) between the transmitting antennas Tx #1, Tx #2, and Tx #3 of thefirst antenna group is a spacing (D_(Z)+D_(H)) obtained by adding thespacing D_(H) to the horizontal antenna aperture length D_(Z) of thethird antenna group (Rx #1 to Rx #3). Note here that the interelementspacing D_(H) may be the same or a different value as or from thespacings (D_(RH) and 2D_(RH)) between the receiving antennas (Rx #1 toRx #3) of the third antenna group. In FIG. 20A, D_(H)=D_(RH). In thefirst antenna group, the interelement spacing between at least one pairof adjacent transmitting antennas 106 may be a spacing D_(TH), and theinterelement spacing between another pair of adjacent transmittingantennas 106 may be different from the spacing D_(TH).

Further, in FIG. 20A, the horizontal positions of the transmittingantennas Tx #4 and Tx #5 of the second antenna group are positionsdisplaced by spacings D_(T2H1) and D_(T2H2), respectively, inward in ahorizontal direction within the range of horizontal aperture of thefirst antenna group (in FIG. 20A, within the range inside the horizontalpositions of the end-point antennas Tx #1 and Tx #3) from the horizontalposition of any antenna of the first antenna group (Tx #1, Tx #2, and Tx#3). In FIG. 20A, the transmitting antennas Tx #4 and Tx #5 of thesecond antenna group are placed in positions displaced by spacingsD_(T2H1) and D_(T2H2), respectively, from the horizontal position of Tx#3.

For example, as shown in FIG. 20A, in a case where the horizontalposition of the fourth antenna (Rx #4) is on the outer side (in FIG.20A, the right side) of the horizontal position of the rightmost antennaRx #3 of the third antenna group, the interelement spacing betweenantennas in the third antenna group based on the leftmost antenna Rx #1of the third antenna group (in the case of FIG. 20A, the spacing D_(RH)between Rx #1 and Rx #2 or the spacing 2D_(RH) between Rx #1 and Rx #3)may be used as the spacing D_(T2H1) or D_(T2H2) from the horizontalposition of the rightmost antenna Tx #3 (or the antenna Tx #2, which isnot an end point) of the first antenna group.

Further, in a case (not illustrated) where the horizontal position ofthe fourth antenna (Rx #4) is on the outer side (in FIG. 20A, the leftside) of the horizontal position of the leftmost antenna Rx #1 of thethird antenna group, the interelement spacing between antennas in thethird antenna group based on the rightmost antenna Rx #3 of the thirdantenna group (for example, in the case of the third antenna group shownin FIG. 20A, the spacing 2D_(RH) between Rx #3 and Rx #2 or the spacing2D_(RH) between Rx #3 and Rx #1) may be used as the spacing D_(T2H1) orD_(T2H2) from the horizontal position of the leftmost antenna Tx #1 (orthe antenna Tx #2, which is not an end point) of the first antennagroup.

Further, in FIG. 20A, the vertical positions of the transmittingantennas Tx #4 and Tx #5 of the second antenna group are positions thatare at spacings D_(TV1) and D_(TV2), respectively, from the verticalposition of the first antenna group (Tx #1, Tx #2, and Tx #3).

Note here that the spacings D_(TV1) and D_(TV2) are spacings that aredifferent from the vertical spacing D_(RV) between the third antennagroup and the fourth antenna. In other words, the spacings D_(TV1) andD_(TV2) and the spacing D_(RV) need only be set so that in a case wherethe first antenna group (Tx #1, Tx #2, and Tx #3) and the third antennagroup (Rx #1 to Rx #3) are identical (if made to agree) in verticalposition with each other, the vertical position (reference position) ofthe first and third antenna groups, the vertical position of each of thetransmitting antennas (Tx #4 and Tx #5) of the second antenna group, andthe vertical position of the fourth antenna are different positions(i.e. do not overlap).

As shown in FIG. 20A, the arrangement of the transmitting antennas Tx #1to Tx #5 that constitute the transmitting array antenna is anarrangement in which the antennas do not overlap in a verticaldirection, as in the embodiments described above. For this reason, thevertical size of the transmitting antennas Tx #1 to Tx #5 thatconstitute the transmitting array antenna can be an arbitrary size.Similarly, as shown in FIG. 20A, the arrangement of the receivingantennas Rx #1 to Rx #4 that constitute the receiving array antenna isan arrangement in which the antennas do not overlap in a verticaldirection, as in the embodiments described above. For this reason, thevertical size of the receiving antennas Rx #1 to Rx #4 that constitutethe receiving array antenna can be an arbitrary size.

The arrangement of the virtual receiving array (virtual antennas VA #1to VA #20) shown in FIG. 20B, which is constituted by the antennaarrangement shown in FIG. 20A described above, has the followingcharacteristics.

The virtual receiving array shown in FIG. 20B is configured to include ahorizontal virtual linear array antenna HLA composed of nine virtualantennas (VA #1, VA #6, VA #11, VA #2, VA #7, VA #12 (VA #20), VA #3, VA#8, and VA #13 (VA #20) surrounded by dashed lines shown in FIG. 20B)arranged in a straight line at interelement spacings D_(RH) (regularspacings) in a horizontal direction. That is, the number of virtualantennas that are lined up in a straight line in a horizontal directionhas such a relationship as to be the product (in FIG. 20A, 9) of thenumber of antennas (in FIG. 20A, 3) of the first antenna group and thenumber of antennas (in FIG. 20A, 3) of the third antenna group.

Further, the virtual receiving array shown in FIG. 20B is configured toinclude a vertical virtual linear array antenna VLA composed of fourvirtual antennas (VA #17, VA #3, VA #10, and VA #14 surrounded by dashedlines shown in FIG. 20B) arranged in a straight line in a verticaldirection. The number of virtual antennas that are lined up in astraight line in a vertical direction has such a relationship as to be“(Number of Antennas of Second Antenna Group)+(Number of Antennas ofFourth Antenna)+1” (in FIG. 20B, 4).

In this way, with the limited number Nt of transmitting antennas being 5and the limited number Na of receiving antennas being 4, the arrangementof antennas that constitute a transmitting array antenna and a receivingarray antenna shown in FIG. 20A allows the arrangement of the virtualreceiving array (VA #1, . . . , VA #20) shown in FIG. 20B to be anarrangement of nine antennas (HLA) in a straight line in a horizontaldirection and four antennas (VLA) in a straight line in a verticaldirection, thus making it possible to maximally enlarge the aperturelengths of the virtual receiving array.

(3) Although the foregoing embodiments have described cases where acoded pulse radar is used, the present disclosure is also applicable toa radar system, such as a chirp pulse radar, that usesfrequency-modulated pulse waves.

(4) In the radar apparatus 10 shown in FIG. 1, the radar transmitter 100and the radar receiver 200 may be individually placed in physicallyseparated places.

(5) Although not illustrated, the radar apparatus 10 includes, forexample, a central processing unit (CPU), a storage medium (read-onlymemory (ROM)) having a control program stored thereon, and a workingmemory such as a RAM (random-access memory). In this case, the functionsof the components described above are achieved by the CPU executing thecontrol program. Note, however, that the radar apparatus 10 is notlimited in hardware configuration to such an example. For example, thefunctional components of the radar apparatus 10 may be achieved as ICs(integrated circuits). These functional components may take the form ofindividual single chips or of a single chip including some or all of thefunctional components.

In the foregoing, various embodiments have been described with referenceto the drawings. However, the present disclosure is of course notlimited to such examples. It is apparent that persons skilled in the artcan conceive of various changes and alterations within the scope ofclaims, and such changes and alterations are naturally understood aspertaining to the technical scope of the present disclosure. Eachconstituent element in the embodiments described above may bearbitrarily combined with the other without departing from the spirit ofthe disclosure.

Although each of the foregoing embodiments has been described by givingan example where the present disclosure is configured with hardware, thepresent disclosure may alternatively be achieved with software incooperation with hardware.

Further, the functional blocks used in the description of eachembodiment described above are typically achieved as LSIs, which areintegrated circuits. The integrated circuits may control the functionalblocks used in the description of the embodiments above and each includean input terminal and an output terminal. These LSIs may take the formof individual single chips or of a single chip including some or all ofthem. Depending on the degree of integration, the LSIs may alternativelybe referred to as “ICs”, “system LSIs”, “super LSIs”, or “ultra LS Is”.

However, the technique of implementing an integrated circuit is notlimited to the LSI and may be realized by using a dedicated circuit or ageneral-purpose processor. In addition, an FPGA (field-programmable gatearray) that can be programmed after the manufacture of the LSI or areconfigurable processor in which the connections and the settings ofcircuit cells disposed inside the LSI can be reconfigured may be used.

If future integrated circuit technology replaces LSIs as a result of theadvancement of semiconductor technology or other derivative technology,the functional blocks could be integrated using the future integratedcircuit technology. Biotechnology can also be applied.

Summary of the Present Disclosure

A radar apparatus of the present disclosure includes: a radartransmitter that transmits a radar signal through a transmitting arrayantenna; and a radar receiver that receives, through a receiving arrayantenna, a reflected-wave signal produced by the radar signal beingreflected by a target. The transmitting array antenna is composed of afirst antenna group including a plurality of transmitting antennasarranged in a first direction and a second antenna group including atleast one transmitting antenna placed in a position inside at least onepair of adjacent transmitting antennas of the first antenna group in thefirst direction and a position different from the first antenna group ina second direction orthogonal to the first direction. The receivingarray antenna is composed of a third antenna group including a pluralityof receiving antennas arranged in the first direction and a fourthantenna that is one receiving antenna placed in a position outside anend of the third antenna group in the first direction and a positiondifferent from the third antenna group in the second direction. Aninterelement spacing between the adjacent transmitting antennas in thefirst direction is a sum of an aperture length of the third antennagroup and a spacing between the third antenna group and the fourthantenna in the first direction. An interelement spacing in the firstdirection between a receiving antenna of the third antenna group locatedat an end on a second side opposite to a first side close to theposition in which the fourth antenna is placed and each of the otherantennas of the third antenna group is identical to an interelementspacing in the first direction between a transmitting antenna of theadjacent transmitting antennas located on the same side as the firstside and each of the transmitting antennas of the second antenna group.In a case where the first antenna group and the third antenna group areidentical in position in the second direction, a position of each of thetransmitting antennas of the second antenna group in the seconddirection and a position of the fourth antenna in the second directionare different.

In the radar apparatus of the present disclosure, interelement spacingsbetween the plurality of receiving antennas of the third antenna groupare equal.

In the radar apparatus of the present disclosure, interelement spacingsbetween the plurality of receiving antennas of the third antenna groupand a spacing between the third antenna group and the fourth antenna inthe first direction are equal.

In the radar apparatus of the present disclosure, interelement spacingsbetween the plurality of receiving antennas of the third antenna groupare different.

In the radar apparatus of the present disclosure, interelement spacingsbetween the plurality of receiving antennas of the third antenna groupand a spacing between the third antenna group and the fourth antenna inthe first direction are different.

In the radar apparatus of the present disclosure, in a case where thefirst antenna group and the third antenna group are identical inposition in the second direction, interelement spacings between adjacentantennas in the second direction among the first antenna group, each ofthe transmitting antennas of the second antenna group, and the fourthantenna are regular spacings.

In the radar apparatus of the present disclosure, in a case where thefirst antenna group and the third antenna group are identical inposition in the second direction, interelement spacings between adjacentantennas in the second direction among the first antenna group, each ofthe transmitting antennas of the second antenna group, and the fourthantenna are irregular spacings.

In the radar apparatus of the present disclosure, the second antennagroup includes n (an integer of not less than 1) transmitting antennas,and the third antenna group includes at least (n+1) receiving antennas.

In the radar apparatus of the present disclosure, at least one of thetransmitting and receiving antennas is constituted by a plurality ofsub-array elements arranged in the second direction.

The present disclosure can be realized by software, hardware, orsoftware in cooperation with hardware.

Each functional block used in the description of each embodimentdescribed above can be partly or entirely realized by an LSI such as anintegrated circuit, and each process described in the each embodimentmay be controlled partly or entirely by the same LSI or a combination ofLS Is. The LSI may be individually formed as chips, or one chip may beformed so as to include a part or all of the functional blocks. The LSImay include a data input and output coupled thereto. The LSI here may bereferred to as an IC, a system LSI, a super LSI, or an ultra LSIdepending on a difference in the degree of integration.

However, the technique of implementing an integrated circuit is notlimited to the LSI and may be realized by using a dedicated circuit, ageneral-purpose processor, or a special-purpose processor. In addition,an FPGA (field-program mable gate array) that can be programmed afterthe manufacture of the LSI or a reconfigurable processor in which theconnections and the settings of circuit cells disposed inside the LSIcan be reconfigured may be used. The present disclosure can be realizedas digital processing or analogue processing.

If future integrated circuit technology replaces LSIs as a result of theadvancement of semiconductor technology or other derivative technology,the functional blocks could be integrated using the future integratedcircuit technology. Biotechnology can also be applied.

The present disclosure is applicable as a radar apparatus that performsdetection in a wide angular range.

What is claimed is:
 1. A radar apparatus comprising: a radar transmitterthat transmits a radar signal through a transmitting array antenna; anda radar receiver that receives, through a receiving array antenna, areflected-wave signal produced by the radar signal being reflected by atarget, wherein one of the transmitting array antenna and the receivingarray antenna includes a first plurality of antennas arranged in a firstdirection and a second plurality of antennas, wherein the firstplurality of antennas are arranged at different positions in the firstdirection, wherein each of the second plurality of antennas is arrangedat a different position from a corresponding one of the first pluralityof antennas in the first direction and in a second direction orthogonalto the first direction, wherein another one of the transmitting arrayantenna and the receiving array antenna includes a third plurality ofantennas arranged in the first direction and a fourth antenna, whereinthe third plurality of antennas are arranged at different positions inthe first direction, wherein the fourth antenna is arranged at adifferent position from each of the third plurality of antennas in thefirst direction and in the second direction, and wherein an antennaaperture length of the first plurality of antennas and the secondplurality of antennas is the same as an antenna aperture length of thethird plurality of antennas and the fourth antenna.
 2. The radarapparatus according to claim 1, wherein interelement spacings betweenthe third plurality of antennas are equal.
 3. The radar apparatusaccording to claim 1, wherein the third plurality of antennas and thefourth antenna are arranged with equal spacings in the first direction.4. The radar apparatus according to claim 1, wherein interelementspacings between the third plurality of antennas are different.
 5. Theradar apparatus according to claim 1, wherein an interelement spacing oftwo of the third plurality of antennas from the fourth antenna in thefirst direction differs from interelement spacings of the remainingantennas in the first direction.
 6. The radar apparatus according toclaim 1, wherein the second plurality of antennas include n antennas, nbeing an integer of not less than 1, and the third plurality of antennasinclude at least (n+1) antennas.
 7. The radar apparatus according toclaim 1, wherein at least one of the transmitting array antenna and thereceiving array antenna are constituted by a plurality of sub-arrayelements arranged in the second direction.